RNAi沉默淀粉分支酶基因SBEI对玉米直链淀粉合成的影响

淀粉分支酶(SBE)是淀粉合成的限速酶。为了研究SBEI沉默对直链淀粉合成的影响, 克隆了玉米(Zea mays)淀粉分支酶SBEI基因片段, 构建了SBEI的RNAi表达载体pBAC418, 用基因枪将其导入玉米自交系幼胚愈伤组织, 经木糖筛选获得了7株转化再生植株。利用FAD2 intron和xylA基因探针对T₀代再生玉米植株进行DNA dot blot和PCR-Southern检测, 证实5株为阳性植株, 其中4株正常结实。SBEI基因沉默对阳性再生玉米株系籽粒的含油量没有显著影响; 蛋白质含量显著高于受体对照; 总淀粉含量与对照相比无显著差异, 转基因株系直链淀粉含量平均提高了9.8%。     

Isoprenoid biosynthesis via a mevalonate-independent pathway in plants: cloning and heterologous expression of 1-deoxy-D-xylulose-5-phosphate reductoisomerase from peppermint

Two distinct pathways are utilized by plants for the biosynthesis of isopentenyl diphosphate, the universal precursor of isoprenoids. The classical acetate/mevalonate pathway operates in the cytosol, whereas plastidial isoprenoids originate via a novel mevalonate-independent route that involves a transketolase-catalyzed condensation of pyruvate and D-glyceraldehyde-3-phosphate to yield 1-deoxy-D-xylulose-5-phosphate as the first intermediate. Based on in vivo feeding experiments, rearrangement and reduction of deoxyxylulose phosphate have been proposed to give rise to 2-C-methyl-D-erythritol-4-phosphate as the second intermediate of this pyruvate/glyceraldehyde-3-phosphate pathway (1-3). The cloning of an Escherichia coli gene encoding an enzyme capable of converting 1-deoxy-D-xylulose-5-phosphate to 2-C-erythritol-4-phosphate was recently reported (4). A cloning strategy was developed for isolating the gene encoding a plant homolog of this enzyme from peppermint (Mentha x piperita), and the identity of the resulting cDNA was confirmed by heterologous expression in E. coli. Unlike the microbial reductoisomerase, the plant ortholog encodes a preprotein bearing an N-terminal plastidial transit peptide that directs the enzyme to plastids where the mevalonate-independent pathway operates in plants. The peppermint gene comprises an open reading frame of 1425 nucleotides which, when the plastidial targeting sequence is excluded, encodes a deduced enzyme of approximately 400 amino acid residues with a mature size of about 43.5 kDa.     

Molecular tagging and candidate gene analysis of the high gamma-tocopherol trait in safflower (<Emphasis Type="Italic">Carthamus tinctorius</Emphasis> L.)

Genetic control of the synthesis of high gamma-tocopherol (gamma-T) content in the seed oil of safflower (Carthamus tinctorius L.) and development of highly reliable molecular markers for this trait were determined through molecular tagging and candidate gene approaches. An F2 population was developed by crossing the high gamma-T natural mutant IASC-1 with the CL-1 line (standard, high alpha-T profile). This population segregated for the partially recessive gene Tph2. Bulked segregant analysis with random amplified polymorphic DNA (RAPD) and microsatellite (SSR) markers revealed linkage of eight RAPD and one SSR marker loci to the Tph2 gene and allowed the construction of a Tph2 linkage map. RAPD fragments closest to the Tph2 gene were transformed into sequence-characterized amplified region markers. A gamma-T methyltransferase (gamma-TMT) locus was found to co-segregate with Tph2. The locus/band was isolated, cloned and sequenced and it was confirmed as a gamma-TMT gene. A longer partial genomic DNA sequence from this gene was obtained. IASC-1 and CL-1 sequence alignment showed one non-synonymous and two synonymous nucleotide mutations. Intron fragment length polymorphism and insertion-deletion markers based on the gamma-TMT sequence diagnostic for the Tph2 mutation were developed and tested across 22 safflower accessions, cultivars, and breeding lines. The results from this study provide strong support for the role of the gamma-TMT gene in determining high gamma-T content in safflower and will assist introgression of thp2 alleles into elite safflower lines to develop varieties with improved tocopherol composition for specific market niches.     

Seed-specific expression of a bacterial desensitized aspartate kinase increases the production of seed threonine and methionine in transgenic tobacco

In order to study the regulation of threonine and methionine synthesis in plant seeds, tobacco plants were transformed with a chimeric gene containing the coding DNA sequence of a mutant lysC gene from Escherichia coli fused to a promoter from a phaseolin seed storage protein gene. The bacterial mutant lysC gene codes for aspartate kinase (AK) which is desensitized to feedback inhibition by lysine and threonine. Increased AK activity, compared with control non-transformed plants, was detected in seeds but not in leaves, roots and flowers of the transgenic plants. This expression was accompanied by a significant increase in the levels of free threonine and methionine in the seed. The level of these amino acids also correlated positively with the levels of the bacterial enzyme. No alteration in plant phenotype and 'average seed weight' was observed in any of the transgenic plants, indicating that plant growth and seed development were normal. This study demonstrates, for the first time, that the threonine and methionine biosynthetic pathways are active in plant seeds. Thus, targeting of the production of favorable biosynthetic enzymes to plant seeds may represent a desirable molecular approach for production of crop plants with a more balanced nutritional quality.     

长柔毛野豌豆编码甘油-3-磷酸酰基转移酶基因的克隆及序列分析

甘油－3－磷酸酰基转移酶（GPAT）基因与植物抗冷性密切相关。克隆到的长柔毛野豌豆（Vicia villosa)GPAT基因的编码区完整的cDNA片段长1377bp,编码458个氨基酸残基,与蚕豆（Vicia faba)和豌豆（Pissum sativum)比较,其核苷酸序列的同源性分别为94．1％和93．3％,氨基酸序列的同源性分别为96．9％和98．0％。     

Polyhydroxybutyrate synthesis in transgenic flax

Flax (Linum usitatissimum L.) is an annual plant species widely cultivated in temperate climates for bast fibres and linseed oil. Apart from traditional textile use, the fibres are fast becoming an integral part of new composite materials utilized in automobile and constructive industry. Especially attractive for environmental safety demands are biodegradable and renewable biocomposities based on polyhydroxybutyrate (PHB) polymer as a matrix and reinforced with the flax fibres. Manufacturing of PHB by bacteria fermentation is however substantially more expansive as compared to technologies producing conventional plastics. We report for the first time generation of transgenic plants which produce both components of flax/PHB composites, i.e. the fibres and the thermoplastic matrix in the same plant organ of a crop. The flax (cv. Nike) plants were transformed using constructs bearing either single cDNA, encoding the beta-ketothiolase enzyme (C plants), or all three of the genes necessary for poly-beta-hydroxybutyrate (PHB) synthesis (M plants). Both constructs contained a plastidial targeting sequence. The amount of PHB produced by the transgenic plants was up to over 70-fold higher than in wild-type plants, when analysed using the gas chromatography/mass spectrometry (GC-MS method). The PHB accumulation in plastids caused change both in their shape and size. The use of a stem-specific promoter for transgene expression protected the transgenic plant from growth retardation and also provided higher PHB synthesis than in the case of constructs governed by the 35S CaMV constitutive promoter. None toxic effects that could lead to stunted growth or the loss of fertility were observed, when 14-3-3 promoter was used as the stem-specific. Significant modifications in stem mechanical properties were accompanied to the PHB accumulation in growing cell of fibres in the transgenic plants. The Young's modulus E, the average measure of stem tissues resistance to tensile loads increased up to twice in M plants as compared to a single gene transformed ones. However, a wide range of E values, from 24.1 to 54.4 MPa, was observed in dependence of tested strain. Potential commercial significance of the genetic manipulation approach enabling synthesis of thermoplastic in crops cultivated for fibres is discussed.     

Targeting of the Arabidopsis homomeric acetyl-coenzyme A carboxylase to plastids of rapeseeds.

Acetyl-coenzyme A carboxylase (ACCase) occurs in at least two forms in rapeseed (Brassica napus): a homomeric (HO) and presumably cytosolic isozyme and a heteromeric, plastidial isozyme. We investigated whether the HO-ACCase of Arabidopsis can be targeted to plastids of B. napus seeds. A chloroplast transit peptide and the napin promoter were fused to the Arabidopsis ACC1 gene and transformed into B. napus, with the following results. (a) The small subunit transit peptide was sufficient to provide import of this very large protein into developing seed plastids. (b) HO-ACCase in isolated plastids was found to be biotinylated at a level comparable to extraplastidial HO-ACCase. (c) In vitro assays of HO-ACCase in isolated plastids from developing seeds indicate that it occurs as an enzymatically active form in the plastidial compartment. (d) ACCase activity in mature B. napus seeds is normally very low; however, plants expressing the SSU/ACC1 gene had 10- to 20-fold higher ACCase activity in mature seeds, suggesting that plastid localization prevents the turnover of HO-ACCase. (e) ACCase over-expression altered seed fatty acid composition, with the largest effect being an increase approximately 5% by the expression of HO-ACCase in plastids.     

A modified <Emphasis Type="Italic">in planta</Emphasis> method of <Emphasis Type="Italic">Agrobacterium</Emphasis>-mediated transformation enhances the transformation efficiency in safflower (<Emphasis Type="Italic">Carthamus tinctorius</Emphasis> L.)

Plant transformation has emerged as an important tool to integrate foreign genes in the plant genome to modify the plants for desired traits. Though many techniques of plant transformation are available; getting single copy transgenic events and cost associated remains a big challenge. Thus Agrobacterium-mediated transformation remains the method of choice due to multiple advantages. In the present work a tissue culture free protocol of Agrobacterium-mediated transformation was optimized in safflower, an oil seed crop recalcitrant to transformation. As a proof of concept we selected pCAMBIA2300 gene cassette containing Arabidopsis specific delta 15 desaturase (FAD3) downstream to truncated seed specific promoter beta-conglycinin and optimized tissue culture free protocol of Agrobacterium-mediated transformation using embryos as explants. Addition of silwet L-77, sonication treatment, vacuum infiltration in infection medium and use of paper wicks in co-cultivation period increased the transformation efficiency to 19.3%. Further, success in transformation was confirmed via product accumulation in 21 independent transgenic events wherein oil in transformed seeds showed significant accumulation of alpha-linolenic acid (ALA; 18:3; n3) which is generated from linoleic acid (LA; 18:2; n3) in a FAD3 catalyzed reaction. The present protocol can be utilized to produce transgenic safflower with different desired characters.     

Effects of foliar application of 6-benzylaminopurine on yield and oil content in two spring safflower (Carthamus tinctorius L.) cultivars

To study the effect of an exogenous cytokinin application on safflower yield, an experiment was conducted in 2012–2013. Two cultivars of safflower (Goldasht and Zendehrood) and five concentrations of 6-benzylaminopurine (BAP) (0, 25, 50, 75, and 100 μM) were applied at the flowering stage. Results indicated that the application of 75 μM of BAP showed increased seed and oil yield by 17.54 and 18.29 % over the control, respectively. The increase in seed yield by application of BAP was attributed to the increase in characters like number of heads per plant, number of seeds per head, and 1,000 seed weight. Applying of BAP increased oil content compared with the control. To determine the concentration of cytokinin which has the highest performance for increasing seed yield, regression analysis were estimated showing that in the Zendehrood cultivar, the application of 43 μM of BAP produced the highest seed yield, and in the Goldasht cultivar the application of 73 μM of BAP during flowering produced the highest seed yield.     

Seed‐specific RNAi in safflower generates a superhigh oleic oil with extended oxidative stability

Vegetable oils extracted from oilseeds are an important component of foods, but are also used in a range of high value oleochemical applications. Despite being biodegradable, nontoxic and renewable current plant oils suffer from the presence of residual polyunsaturated fatty acids that are prone to free radical formation that limit their oxidative stability, and consequently shelf life and functionality. Many decades of plant breeding have been successful in raising the oleic content to ~90%, but have come at the expense of overall field performance, including poor yields. Here, we engineer superhigh oleic (SHO) safflower producing a seed oil with 93% oleic generated from seed produced in multisite field trials spanning five generations. SHO safflower oil is the result of seed‐specific hairpin‐based RNA interference of two safflower lipid biosynthetic genes, FAD2.2 and FATB, producing seed oil containing less than 1.5% polyunsaturates and only 4% saturates but with no impact on lipid profiles of leaves and roots. Transgenic SHO events were compared to non‐GM safflower in multisite trial plots with a wide range of growing season conditions, which showed no evidence of impact on seed yield. The oxidative stability of the field‐grown SHO oil produced from various sites was 50 h at 110°C compared to 13 h for conventional ~80% oleic safflower oils. SHO safflower produces a uniquely stable vegetable oil across different field conditions that can provide the scale of production that is required for meeting the global demands for high stability oils in food and the oleochemical industry.     

Introduction of the cDNA for shape Arabidopsis glycerol-3-phosphate acyltransferase (GPAT) confers unsaturation of fatty acids and chilling tolerance of photosynthesis on rice

The chilling sensitivity of several plant species is closely correlated with the levels of unsaturation of fatty acids in the phosphatidylglycerol (PG) of chloroplast membranes. Plants with a high proportion of unsaturated fatty acids, such as Arabidopsis thaliana, are resistant to chilling, whereas species like squash with only a low proportion are rather sensitive to chilling. The glycerol-3-phosphate O-acyltransferase (GPAT) enzyme of chloroplasts plays an important role in determining the levels of PG fatty acid desaturation.A cDNA for oleate-selective GPAT of Arabidopsis under the control of a maize Ubiquitin promoter was introduced into rice (Oryza sativa L.) using the Agrobacterium-mediated gene transfer method. The levels of unsaturated fatty acids in the phosphatidylglycerol of transformed rice leaves were found to be 28% higher than that of untransformed controls. The net photosynthetic rate of leaves of transformed rice plants was 20% higher than that of the wild type at 17°C. Thus, introduction of cDNA for the Arabidopsis GPAT causes greater unsaturation of fatty acids and confers chilling tolerance of photosynthesis on rice.     

Potential for seed-mediated gene flow in agroecosystems from transgenic safflower (Carthamus tinctorius L.) intended for plant molecular farming

Safflower has been transformed for field scale molecular farming of high-value proteins including several pharmaceuticals. Viable safflower seed remaining in the soil seed bank after harvest could facilitate seed and pollen-mediated gene flow. Seeds may germinate in subsequent years and volunteer plants may flower and potentially outcross with commodity safflower and/or produce seed. Seeds from volunteers could become admixed with conventional crops at harvest, and/or replenish the seed bank. Seed in following crops could be transported locally and internationally and facilitate gene flow in locations where regulatory thresholds and public acceptance differ from Canada. Seed-mediated gene flow was examined in three studies. Safflower seed loss and viability following harvest of commercial fields of a non-transgenic cultivar were determined. We assessed seed longevity of transgenic and non-transgenic safflower, on the soil surface and buried at two depths. Finally, we surveyed commercial safflower fields at different sites and measured density and growth stage of safflower volunteers, in other crops the following year and documented volunteer survival and viable seed production. Total seed loss at harvest in commercial fields, ranged from 231 to 1,069 seeds m⁻² and the number of viable seeds ranged from 81 to 518 seeds m⁻². Safflower has a relatively short longevity in the seed bank and no viable seeds were found after 2 years. Based on the seed burial studies it is predicted that winter conditions would reduce safflower seed viability on the soil surface by >50%, leaving between 40 and 260 viable seeds m⁻². The density of safflower volunteers emerging in the early spring of the following year ranged from 3 to 11 seedlings m⁻². Safflower volunteers did not survive in fields under chemical fallow, but in some cereal fields small numbers of volunteers did survive and generate viable seed. Results will be used to make recommendations for best management practices to reduce seed-mediated gene flow from commercial production of plant molecular farming with safflower.     

Functional analysis of the essential bifunctional tobacco enzyme 3-dehydroquinate dehydratase/shikimate dehydrogenase in transgenic tobacco plants

In plants, the shikimate pathway occurs in the plastid and leads to the biosynthesis of aromatic amino acids. The bifunctional 3-dehydroquinate dehydratase/shikimate dehydrogenase (DHD/SHD) catalyses the conversion of dehydroquinate into shikimate. Expression of NtDHD/SHD was suppressed by RNAi in transgenic tobacco plants. Transgenic lines with <40% of wild-type activity displayed severe growth retardation and reduced content of aromatic amino acids and downstream products such as cholorogenic acid and lignin. Dehydroquinate, the substrate of the enzyme, accumulated. However, unexpectedly, so did the product, shikimate. To exclude that this finding is due to developmental differences between wild-type and transgenic plants, the RNAi approach was additionally carried out using a chemically inducible promoter. This approach revealed that the accumulation of shikimate was a direct effect of the reduced activity of NtDHD/SHD with a gradual accumulation of both dehydroquinate and shikimate following induction of gene silencing. As an explanation for these findings the existence of a parallel extra-plastidic shikimate pathway into which dehydroquinate is diverted is proposed. Consistent with this notion was the identification of a second DHD/SHD gene in tobacco (NtDHD/SHD-2) that lacked a plastidic targeting sequence. Expression of an NtDHD/SHD-2-GFP fusion revealed that the NtDHD/SHD-2 protein is exclusively cytosolic and is capable of shikimate biosynthesis. However, given the fact that this cytosolic shikimate synthesis cannot complement loss of the plastidial pathway it appears likely that the role of the cytosolic DHD/SHD in vivo is different from that of the plastidial enzyme. These data are discussed in the context of current models of plant intermediary metabolism.     

Arabidopsis AtGPAT1, a member of the membrane-bound glycerol-3-phosphate acyltransferase gene family,is essential for tapetum differentiation and male fertility

Membrane-bound glycerol-3-phosphate acyltransferase (GPAT; EC 2.3.1.15) mediates the initial step of glycerolipid biosynthesis in the extraplastidic compartments of plant cells. Here, we report the molecular characterization of a novel GPAT gene family from Arabidopsis, designated AtGPAT. The corresponding polypeptides possess transmembrane domains and GPAT activity when expressed heterologously in a yeast lipid mutant. The functional significance of one isoform, AtGPAT1, is the focus of the present study. Disruption of the AtGPAT1 gene causes a massive pollen development arrest, and subsequent introduction of the gene into the mutant plant rescues the phenotype, illustrating a pivotal role for AtGPAT1 in pollen development. Microscopic examinations revealed that the gene lesion results in a perturbed degeneration of the tapetum, which is associated with altered endoplasmic reticulum profiles and reduced secretion. In addition to the sporophytic effect, AtGPAT1 also exerts a gametophytic effect on pollen performance, as the competitive ability of a pollen grain to pollinate is dependent on the presence of an AtGPAT1 gene. Deficiency in AtGPAT1 correlates with several fatty acid composition changes in flower tissues and seeds. Unexpectedly, however, a loss of AtGPAT1 causes no significant change in seed oil content.     

Rat sn-glycerol-3-phosphate acyltransferase: molecular cloning and characterization of the cDNA and expressed protein.

Rat mitochondrial glycerol-3-phosphate acyltransferase (GPAT) cDNA was cloned and characterized. We identified a cDNA containing an open reading frame of 828 amino acids that had an 89% homology with the coding region of the previously characterized mouse mitochondrial GPAT and a predicted amino acid sequence that was 96% identical. The rat 5' UTR was only 159 nucleotides, in contrast to the 926 nucleotide 5' UTR of the mouse cDNA and had an internal deletion of 167 nucleotides. GPAT was expressed in Sf21 insect cells, and specific inhibitors strongly suggest that, like the Escherichia coli GPAT, the recombinant mitochondrial GPAT and the mitochondrial GPAT isoform in rat liver contain critical serine, histidine, and arginine residues.     

Modification of seed oil content and acyl composition in the brassicaceae by expression of a yeast sn-2 acyltransferase gene.

A putative yeast sn-2 acyltransferase gene (SLC1-1), reportedly a variant acyltransferase that suppresses a genetic defect in sphingolipid long-chain base biosynthesis, has been expressed in a yeast SLC deletion strain. The SLC1-1 gene product was shown in vitro to encode an sn-2 acyltransferase capable of acylating sn-1 oleoyl-lysophosphatidic acid, using a range of acyl-CoA thioesters, including 18:1-, 22:1-, and 24:0-CoAs. The SLC1-1 gene was introduced into Arabidopsis and a high erucic acid-containing Brassica napus cv Hero under the control of a constitutive (tandem cauliflower mosaic virus 35S) promoter. The resulting transgenic plants showed substantial increases of 8 to 48% in seed oil content (expressed on the basis of seed dry weight) and increases in both overall proportions and amounts of very-long-chain fatty acids in seed triacylglycerols (TAGs). Furthermore, the proportion of very-long-chain fatty acids found at the sn-2 position of TAGs was increased, and homogenates prepared from developing seeds of transformed plants exhibited elevated lysophosphatidic acid acyltransferase (EC 2.3.1.51) activity. Thus, the yeast sn-2 acyltransferase has been shown to encode a protein that can exhibit lysophosphatidic acid acyltransferase activity and that can be used to change total fatty acid content and composition as well as to alter the stereospecific acyl distribution of fatty acids in seed TAGs.     

sn-1-Acylglycerol-3-phosphate acyltransferase of Escherichia coli causes insertion of cis-11 eicosenoic acid into the sn-2 position of transgenic rapeseed oil

The plsC gene of Escherichia coli encoding sn-1-acylglycerol-3-phosphate acyltransferase was modified by inserting an endoplasmic reticulum retrieval signal to its 3 end and introduced into rapeseed (Brassica napus L.) plants under the control of a napin promotor. In developing seeds from transgenic plants an sn-1-acylglycerol-3-phosphate acyltransferase activity was detectable which showed substrate specificities typical of the E. coli enzyme. Moreover, seed oil from the transformants unlike that from untransformed plants contained substantial amounts of triacylglycerol species esterified with very-long-chain fatty acids at each glycerol position. Analysis of fatty acids at the sn-2 position of triacylglycerol showed hardly any very-long-chain fatty acids in untransformed plants, but in certain transformants these fatty acids were present, namely about 4% erucic acid and 9% eicosenoic acid. These data demonstrate that the bacterial acyltransferase can function in developing rapeseed and alters the stereochemical composition of transgenic rape seed oil by directing very-long-chain fatty acids, especially cis-11 eicosenoic acid, to its sn-2 position.