Tissue-specific expression in transgenic maize of four endosperm promoters from maize and rice

The tissue-specific, developmental, and genetic control of four endosperm-active genes was studied via expression of GUS reporter genes in transgenic maize plants. The transgenes included promoters from the maize granule-bound starch synthase (Waxy) gene (zmGBS), a maize 27 kDa zein gene (zmZ27), a rice small subunit ADP-glucose pyrophosphorylase gene (osAGP) and the rice glutelin 1 gene (osGT1). Most plants had a transgene expression profile similar to that of the endogenous gene: expression in the pollen and endosperm for the zmGBS transgene, and endosperm only for the others. Histological analysis indicated expression initiated at the periphery of the endosperm for zmGBS, zmZ27 and osGT1, while osAGP transgene activity tended to start in the lower portion of the seed. Transgene expression at the RNA level was proportional to GUS activity, and did not influence endogenous gene expression. Genetic analysis showed that there was a positive dosage response with most lines. Activity of the zmGBS transgene was threefold higher in a low starch (shrunken2) genetic background. This effect was not seen with zmZ27 or osGT1 transgenes. The expression of the transgenes is discussed relative to the known behaviour of the endogenous genes, and the developmental programme of the maize endosperm     

应用B.t.和SBTi基因提高水稻抗虫性的研究

用基因枪法将单个B.t.基因或与SBTi基因一起导入到两个华南地区优良籼稻品种中,获得21个转B.t.单基因的植株系,4个转B.t.和SBTi双基因的植株系。对R1代植株的分子杂交和遗传分析表明,3个转双基因系中多个拷贝的B.t.和SBTi基因均是整合在植株基因组同一染色体上相同或相近位点。Northern blot证明在R2代转基因植株中B.t.基因稳定表达。对稻纵卷叶螟的抗性实验表明,转B.t.单基因或B.t.和SBTi双基因的转基因植株均较原种对照有更强的抗性,而转双基因植株较转单基因植株又有更强的抗性。     

Expression of RNA-interference/antisense transgenes by the cognate promoters of target genes is a better gene-silencing strategy to study gene functions in rice

Antisense and RNA interference (RNAi)-mediated gene silencing systems are powerful reverse genetic methods for studying gene function. Most RNAi and antisense experiments used constitutive promoters to drive the expression of RNAi/antisense transgenes; however, several reports showed that constitutive promoters were not expressed in all cell types in cereal plants, suggesting that the constitutive promoter systems are not effective for silencing gene expression in certain tissues/organs. To develop an alternative method that complements the constitutive promoter systems, we constructed RNAi and/or antisense transgenes for four rice genes using a constitutive promoter or a cognate promoter of a selected rice target gene and generated many independent transgenic lines. Genetic, molecular, and phenotypic analyses of these RNAi/antisense transgenic rice plants, in comparison to previously-reported transgenic lines that silenced similar genes, revealed that expression of the cognate promoter-driven RNAi/antisense transgenes resulted in novel growth/developmental defects that were not observed in transgenic lines expressing constitutive promoter-driven gene-silencing transgenes of the same target genes. Our results strongly suggested that expression of RNAi/antisense transgenes by cognate promoters of target genes is a better gene-silencing approach to discovery gene function in rice.     

转基因水稻胚乳中表达铁结合蛋白提高稻米铁含量

为提高我国稻米的铁含量,通过农杆菌介导将自行克隆的菜豆(Phaseolus limensis)铁结合蛋白(Ferritin)基因导入了一个高产粳稻(Oryaz sativa L.ssp．japonuica)品种中,获得17个独立的转基因水稻株系。分子检测证明,外源基因在多数转基因水稻植株基因组中有1～3个整合位点,并可稳定遗传。在水稻种子贮存蛋白谷蛋白基因GluB-1启动子的控制下,铁结合蛋白基因可在转基因水稻的种子中高效特异地表达,不同转化子中的表达量有明显不同。在转基因水稻种子中表达铁结合蛋白后对提高精米中的铁含量有明显的效果,相对于未转化对照最多可提高64％,而锌的含量并无明显变化。     

Over-expression of AGPase genes enhances seed weight and starch content in transgenic maize

Cereal crops accumulate starch in the seed endosperm as an energy reserve. ADP-glucose pyrophosphorylase (AGPase) plays a key role in regulating starch biosynthesis in cereal seeds. The AGPase in the maize endosperm is a heterotetramer of two small subunits, encoded by Brittle2 (Bt2) gene, and two large subunits, encoded by the Shrunken2 (Sh2) gene. The two genes (Bt2, Sh2) from maize were introduced into two elite maize inbred lines, solely and in tandem, and under the control of endosperm-specific promoters for over-expression. PCR, Southern blotting, and real-time RT-PCR analysis indicated that the transgenes were integrated into the genome of transgenic plants and were over-expressed in their progeny. The over-expression of either gene enhanced AGPase activity, seed weight and starch content compared with the WT, but the amounts were lower than plants with over-expression of both Bt2 and Sh2. Developing seeds from co-expression transgenic maize plants had higher cytoplasmic AGPase activity: the 100-grain weight increased 15% over the wild type (WT), and the starch content increased to over 74% compared with the WT of 65%. These results indicate that over-expression of the genes in transgenic maize plants could improve kernel traits. This report provides a feasible approach for increasing starch content and seed weight in maize.     

Targeted transcriptomic and metabolic profiling reveals temporal bottlenecks in the maize carotenoid pathway that may be addressed by multigene engineering

Carotenoids are a diverse group of tetraterpenoid pigments found in plants, fungi, bacteria and some animals. They play vital roles in plants and provide important health benefits to mammals, including humans. We previously reported the creation of a diverse population of transgenic maize plants expressing various carotenogenic gene combinations and exhibiting distinct metabolic phenotypes. Here we performed an in‐depth targeted mRNA and metabolomic analysis of the pathway to characterize the specific impact of five carotenogenic transgenes and their interactions with 12 endogenous genes in four transgenic lines representing distinct genotypes and phenotypes. We reconstructed the temporal profile of the carotenoid pathway during endosperm development at the mRNA and metabolic levels (for total and individual carotenoids), and investigated the impact of transgene expression on the endogenous pathway. These studies enabled us to investigate the extent of any interactions between the introduced transgenic and native partial carotenoid pathways during maize endosperm development. Importantly, we developed a theoretical model that explains these interactions, and our results suggest genetic intervention points that may allow the maize endosperm carotenoid pathway to be engineered in a more effective and predictable manner.     

Variable T-DNA linkage configuration affects inheritance of carotenogenic transgenes and carotenoid accumulation in transgenic indica rice

Transgenics for the expression of β-carotene biosynthetic pathway in the endosperm were developed in indica rice background by introducing phytoene synthase (psy) and phytoene desaturase (crtI) genes through Agrobacterium-mediated transformation, employing non-antibiotic positive selectable marker phosphomannose isomerase (pmi). Twenty-seven transgenic lines were characterized for the structural organization of T-DNA inserts and the expression of transgenes in terms of total carotenoid and β-carotene accumulation in the endosperm. Ten lines were also studied for the inheritance of transgenic loci to the T₁ progenies. Copy number and sites of integration of the transgenes ranged from one to four. Almost 50% of the transgenic lines showed rearrangement of T-DNA inserts. However, most of the rearrangements occurred in the crtI expression cassette which is adjacent to the right T-DNA border. Differences in copy numbers of psy and crtI were also observed indicating partial T-DNA integration. Beyond T-DNA border transfer was also detected in 25% of the lines. Fifty percent of the lines studied showed single Mendelian locus inheritance, while two lines showed bi-locus inheritance in the T₁ progenies. Some of the lines segregating in 3:1 ratio showed two sites of integration on restriction digestion analysis indicating that the T-DNA insertion sites were tightly linked. Three transgenic lines showed nonparental types in the segregating progenies, indicating unstable transgenic locus. Evidences from the HPLC analysis showed that multiple copies of transgenes had a cumulative effect on the accumulation of carotenoid in the endosperm. T₁ progenies, in general, accumulated more carotenoids than their respective parents, the highest being 6.77 μg/g of polished seeds. High variation in the carotenoid accumulation was observed within the T₁ progenies which could be attributed to the variation in the structural organization and expression of transgenes, minor variations in the genetic background within the progeny plants, or differences in the plant microenvironments. The study identified lines worthy of further multiplication and breeding based on transgene structural integrity in the segregating progeny and high expression levels in terms of the β-carotene accumulation.     

Expression and Inheritance of Nine Transgenes in Rice

A total of 66 transgenic rice cell lines were produced by simultaneously transforming rice callus with nine different plasmids/genes. PCR analysis indicated that the co-transformation frequency of each gene was about 70%. All the cell lines carried at least three genes and 11 cell lines carried all nine genes. Thirty-two fertile transgenic plants (R₀) were generated from the transgenic cell lines and seeds of 32 transgenic R₁ lines and 5 R₂ lines were harvested and analyzed for gene inheritance and protein expression. Progeny segregation analysis indicated that the multiple transgenes were integrated into the same locus of the rice genome, resulting in a 3:1 segregation ratio of the transgenes. Expression analysis of all nine transgenes revealed that the transgenes were expressed in all generations (R₀, R₁, and R₂) and about half of the transgenes from each line were expressed. The expression of one transgene appears to have no effect on the expression of another transgene. Among the 66 cell lines, six lines (9.1%) expressed seven or eight transgenes out of the nine transformed genes. All together, our results showed that multiple genes could be delivered into rice cells simultaneously and cell lines expressing multiple genes could be generated. The results and procedures reported here should be useful in designing multi-plasmid transformation experiments such as those required for plant metabolic engineering.     

The restricted distribution of potato leafroll luteovirus antigen in potato plants with transgenic resistance resembles that in clones with one type of host genemediated resistance

The distribution of virus-infected cells was examined, by fluorescence microscopy, within plants of a range of potato clones infected with potato leafroll luteovirus (PLRV). This range included nine PLRV-resistant clones, of which four were transgenic lines carrying the PLRV coat protein gene and five were conventionally bred. Plants of these clones were resistant to PLRV multiplication and accumulated less virus antigen in leaf tissue than did susceptible clones. Indirect fluorescent antibody staining of thin sections from carbodiimide-fixed petiole tissue revealed that in plants of PLRV-susceptible clones, virus-infected cells were abundant within both external (abaxial) and internal (adaxial) phloem bundles. In plants of the PLRV-resistant conventionally bred clones and in resistant transgenic lines of cv. Pentland Squire, virus-infected cells were much fewer in number and largely restricted to internal phloem bundles. In resistant transgenic lines of cv. Désirée, this restricted distribution of PLRV antigen was only detected in petioles of young leaves. The results suggest that the transgenic and a host-mediated type of resistance that restricts virtis multiplication have underlying similarities.     

Expression of a transgene exchanged by the recombinase-mediated cassette exchange (RMCE) method in plants

We developed a site-directed integration (SDI) system for Agrobacterium-mediated transformation to precisely integrate a single copy of a desired gene into a predefined target locus by recombinase-mediated cassette exchange (RMCE). We produced site-specific transgenic tobacco plants from four target lines and examined expression of the transgene in T1 site-specific transgenic tobacco plants, which were obtained by backcrossing. We found that site-specific transgenic plants from the same target lines showed approximately the same level of expression of the transgene. Moreover, we demonstrated that site-specific transgenic plants showed much less variability of transgene expression than random-integration transgenic plants. Interestingly, transgenes in the same direction at the same target locus showed the same level of activity, but transgenes in different directions showed different levels of activity. The expression levels of transgene did not correlate with those of the target gene. Our results showed that the SDI system could benefit the precise comparisons between different gene constructs, the characterization of different chromosomal regions and the cost-effective screening of reliable transgenic plants.     

Leafy head formation of the progenies of transgenic plants of Chinese cabbage with exogenous auxin genes

The experiment was performed to evaluate the progenies of plant lines transgenic for auxin synthesis genes derived from Ri T-DNA.Four lines of the transgenic plants were self-crossed and the foreign auxin genes in plants of T5 generation were confirmed by Southern hybridization.Two lines,D1232 and D1653,showed earlier folding of expanding leaves than untransformed line and therefore had early initiation of leafy head.Leaf cuttings derived from plant of transgenic line D1653 produced more adventitious roots than the control whereas the cuttings from folding leaves had much more roots than rosette leaves at folding stage,and the cuttings from head leaves had more roots than rosette leaves at heading stage.It is demonstrated that early folding of transgenic leaf may be caused by the relatively higher concentration of auxin.These plant lines with auxin transgenes can be used for the study of hormonal regulation in differentiation and development of plant orgens and for the breeding of new variety with rapid growth trait.     

High accumulation of bioactive peptide in transgenic rice seeds by expression of introduced multiple genes

We have developed a simple binary vector construction system for the simultaneous expression of multiple genes in plants. Up to three independent gene cassettes can be easily integrated into one binary vector using the MultiSite Gateway System. Using this system, we produced transgenic rice plants that accumulated high levels of the hypocholesterolaemic peptide lactostatin (IIAEK) in endosperm. Binary vectors were constructed that could accommodate up to three independent modified glutelin gene cassettes encoding multimer lactostatin in the variable regions. Eight construct permutations were used for rice transformation. We measured the accumulation of lactostatin expressed as a glutelin fusion protein in the mature seeds of 105 independent transgenic rice lines. A general correlation was observed between accumulation level and gene number in the vector constructs, indicating that a higher accumulation of lactostatin was obtained from transgenic rice plants containing the maximum number of gene inserts. These results indicate that this strategy is applicable for the selection of transgenic lines containing large amounts of bioactive peptides in rice seeds.     

Expression of Cholera Toxin B Subunit in Transgenic Rice Endosperm

The synthetic cholera toxin B subunit (CTB) gene, modified according to the optimized codon usage of plant genes, was introduced into a plant expression vector and expressed under the control of the Bx17 HMW (high molecular weight) wheat endosperm-specific promoter containing an intron of the rice act1. The recombinant vector was transformed into rice plants using a biolistic-mediated transformation method. Stable integration of the synthetic CTB gene into the chromosomal DNA was confirmed by PCR amplification analysis. A high level of CTB (2.1% of total soluble protein) was expressed in the endosperm tissue of the transgenic rice plants. The synthetic CTB produced only in the rice endosperm demonstrated strong affinity for G_M1-ganglioside, thereby suggesting that the CTB subunits formed an active pentamer. The successful expression of CTB genes in transgenic plants makes it a powerful tool for the development of a plant-derived edible vaccine.     

Transgenic sugarcane plants expressing high levels of modified cry1Ac provide effective control against stem borers in field trials

To improve transgene expression level, we synthesized a truncated insecticidal gene m-cry1Ac by increasing its GC content from 37.4 to 54.8%, based on the codon usage pattern of sugarcane genes, and transferred it into two sugarcane cultivars (ROC16 and YT79-177) by microprojectile bombardment. The integration sites and expression pattern of the transgene were determined, respectively, by Southern, northern and western blot analyses. The transgenic sugarcane lines produced up to 50?ng Cry1Ac protein per mg soluble proteins, which was about fivefold higher than that produced by the partially modified s-cry1Ac (GC%?=?47.5%). In greenhouse plant assay, about 62% of the transgenic lines exhibited excellent resistance to heavy infestation by stem borers. In field trials, the m-cry1Ac transgenic sugarcane lines expressing high levels of Cry1Ac were immune from insect attack. In contrast, expression of s-cry1Ac in transgenic sugarcane plants resulted in moderately decreased damages in internodes (0.4-1.7%) and stalks (13.3-26.7%) in comparison with the untransformed sugarcane controls, which showed about 4 and 26-40% damaged internodes and stalks, respectively. Significantly, these transgenic sugarcane lines with high levels of insect resistance showed similar agronomic and industrial traits as untransformed control plants. Taken together, the findings from this study indicate a promising potential of engineering an insect-resistant gene to tailor its protein expression levels in transgenic sugarcane to combat insect infestations.     

Transformation of pasta wheat (Triticum turgidum L. var. durum) with high-molecular-weight glutenin subunit genes and modification of dough functionality

Particle bombardment has been used to transform three cultivars (L35, Ofanto, Svevo) and one breeding line (Latino × Lira) of durum wheat (Triticum turgidum L. var. durum). These varieties were co-transformed with plasmids containing selectable and scorable marker genes (bar and uidA) and plasmids containing one of two high-molecular-weight (HMW) glutenin subunit genes (encoding subunits 1Ax1 or 1Dx5). Ten independent transgenic lines were recovered from 1683 bombarded scutella (transformation efficiency thus 0.6%). Five lines expressed either subunit 1Dx5 or 1Ax1 at levels similar to those of endogenous subunits encoded on chromosome 1B. To identify the effects of the transgenes on the functional properties of grain, three lines showing segregation for transgene expression were used to isolate sibling T₂ plants which were null or positive for the transgene product. Analysis of these plants using a small-scale mixograph showed that expression of the additional subunits resulted in increased dough strength and stability, demonstrating that transformation can be used to modify the quality of durum wheat for bread and pasta making.     

Analysis of gene inheritance and expression in hybrids between transgenic sugar beet and wild beets

Reciprocal gene exchange between cultivated sugar beet and wild beets in seed production areas is probably the reason for the occurence of weed beets in sugar beet production fields. Therefore, when releasing transgenic sugar beet plants into the environment, gene transfer to wild beets ( Beta vulgaris ssp. maritima ) has to be considered. In this study the transfer of BNYVV- (beet necrotic yellow vein virus) resistance and herbicide-tolerance genes from two transgenic sugar beet lines that were released in field experiments in 1993 and 1994 in Germany to different wild beet accessions was investigated. In order to evaluate the consequences of outcrossing, manual pollinations of emasculated wild beet plants with homozygous transgenic sugar beet plants were performed. In the resulting hybrids the transgenes were stably inherited according to Mendelian law. Gene expression in leaves and roots of the hybrids was in the same range as in the original transgenic sugar beet plants. Moreover, it was found that in one of the wild beet accessions, transfer and expression of the BNYVV resistance gene did considerably increase the level of virus resistance.