利用Inverse PCR快速筛选单个T-DNA拷贝转基因水稻植株的方法

为了获得单个T-DNA插入拷贝的植株, 我们建立了一套利用Inverse PCR(IPCR)快速检测转基因水稻中T-DNA拷贝数的方法。用IPCR的方法可以扩增出与已知T-DNA序列相邻的水稻基因组DNA未知序列,由此推测转基因水稻植株中T-DNA的拷贝数。我们共对15个转化株系20棵不同植株的DNA进行了IPCR检测。其中12株表现为T-DNA单拷贝插入,3株为双拷贝插入,1株为三拷贝插入。另外4株未检测到T-DNA插入拷贝。IPCR分析结果经过Southern杂交和测序的验证。     

A quick method to estimate the T-DNA copy number in transgenic plants at an early stage after transformation,using inverse PCR

Agrobacterium-mediated transformation of plants is known to result in transgenic plants with a variable number of integrated T-DNA copies [1, 2, 3, 7]. Our aim was to obtain transgenic tobacco plants containing one integrated T-DNA copy per genome. Therefore, a quick method was developed to estimate the T-DNA copy number of young transgenic plantlets within 10 weeks after transformation. Inverse polymerase chain reaction (IPCR) was used to amplify junction fragments, i.e. plant genomic DNA sequences flanking the known T-DNA sequences [5].     

水稻T-DNA插入突变体库的构建及突变类型的分析

利用农杆菌介导的转化系统转化中花11成熟胚愈伤组织,获得1489个独立转化的T-DNA插入再生株系。PCR和Southern杂交的结果表明,69．8％转化株系被整合了T-DNA,通过Tail-PCR也从转化植株中扩增出T-DNA侧翼序列。同时对1066个T1转化株系的抽穗期、株高、单株穗数的调查结果表明,不同株系中分离出了突变植株。     

Estimating the copy number of transgenes in transformed rice by real-time quantitative PCR

In transgenic plants, transgene copy number can greatly influence the expression level and genetic stability of the target gene, making estimation of transgene copy number an important area of genetically modified (GM) crop research. Transgene copy numbers are currently estimated by Southern analysis, which is laborious and time-consuming, requires relatively large amounts of plant materials and may involve hazardous radioisotopes. We report here the development of a sensitive, high-throughput real-time (RT)-PCR technique for estimating transgene copy number in GM rice. This system uses TaqMan quantitative RT-PCR and comparison to a novel rice endogenous reference gene coding for sucrose phosphate synthase (SPS) to determine the copy numbers of the exogenous beta-glucuronidase (GUS) and hygromycin phosphotransferase (HPT) genes in transgenic rice. The copy numbers of the GUS and HPT in primary rice transformants (T0) were calculated by comparing quantitative PCR results of the GUS and HPT genes with those of the internal standard, SPS. With optimized PCR conditions, we achieved significantly accurate estimates of one, two, three and four transgene copies in the T0 transformants. Furthermore, our copy number estimations of both the GUS reporter gene and the HPT selective marker gene showed that rearrangements of the T-DNA occurred more frequently than is generally believed in transgenic rice.     

A simple,rapid and systematic method for the developed GM rice analysis

We generated 383 independent transgenic lines that contained the PsGPD (Glyceraldehyde-3-Phosphate Dehydrogenase), ArCspA (Cold Shock Protein), BrTSR15 (Triple Stress Resistance 15) and BrTSR53 (Triple Stress Resistance 53) genes under the control of a constitutive (CaMV 35S) promoter to generate genetically modified (GM) rice. TaqMan copy number assay was performed to determine the copy numbers of inserted T-DNA. Flanking sequence tags (FSTs) were isolated from 203 single copy T-DNA lines of transgenic plants, and their sequences were mapped to the rice chromosomes. Of the 157 flanking sequence tags that were isolated from single copy lines, transgenes were found to be integrated into genic regions in 58 lines (36 %), whereas 97 lines (62 %) contained transgene insertions in intergenic regions. Approximately 27 putative homozygous lines were obtained through multi-generations of planting, resistance screening and TaqMan copy number assays. To investigate the transgene expression patterns, quantitative real-time PCR analysis was performed using total RNA from leaf tissue of homozygous T1 plants with a single copy and an intergenic insertion of T-DNA. The mRNA expression levels of the examined transgenic rice were significantly increased in all transgenic plants. In addition, myc-tagged 35S:BrTSR15 and 35S:BrTSR53 transgenic plants displayed higher levels of transgene protein. Using numerical data for the mass production of transgenic plants can reduce the time required to obtain a genetically modified plant. Moreover, the duration, cost, and efforts required for transformation can be deliberately predicted. These results may be useful for the large-scale production of transgenic plants or T-DNA inserted rice mutants.     

Transgene behaviour in populations of rice plants transformed using a new dual binary vector system: pGreen/pSoup

Transgene integration, expression level and stability have been studied, across two generations, in a population of rice plants transformed using a new dual binary vector system: pGreen/pSoup. pGreen is a small Ti binary vector unable to replicate in Agrobacterium without the presence of another binary plasmid, pSoup, in the same strain. We engineered both pGreen and pSoup to contain each a different T-DNA. Transformation experiments were conducted using a pGreen vector containing the bar and gusA expression units (no transgene in pSoup) or with a pSoup vector containing an aphIV and gfp expression units (no transgene in pGreen). High plant transformation frequencies (up to 40%) were obtained using herbicide resistance ( bar) or antibiotic resistance ( aphIV) genes. Around 80% of the independently transformed plants expressed unselected reporter genes ( gusA or gfp) present in the vectors. Backbone sequences transfer was frequent (45% of lines) and occurred often in multicopy lines. Around 15-20% of the rice plant lines contained a single T-DNA integration without backbone. Integration of additional transgene copies did not improve expression levels in either T(0) plants or T(1) progenies. Nearly all multicopy lines contained transgenes integrated at several loci in the plant genome, showing that T-DNAs from either pGreen or pSoup frequently integrated at unlinked loci. Precise determination of loci number required the analysis of transgene presence in progeny. Segregation of transgene phenotype was generally misleading and tended to underestimate the real number of transgenic loci. The contribution of this new dual-binary vector system to the development of high-throughput rice transformation systems and to the production of marker-free transgenic rice plants is discussed.     

Generation of single-copy T-DNA transformants in Arabidopsis by the CRE/loxP recombination-mediated resolution system

We investigated whether complex T-DNA loci, often resulting in low transgene expression, can be resolved efficiently into single copies by CRE/loxP-mediated recombination. An SB-loxP T-DNA, containing two invertedly oriented loxP sequences located inside and immediately adjacent to the T-DNA border ends, was constructed. Regardless of the orientation and number of SB-loxP-derived T-DNAs integrated at one locus, recombination between the outermost loxP sequences in direct orientation should resolve multiple copies into a single T-DNA copy. Seven transformants with a complex SB-loxP locus were crossed with a CRE-expressing plant. In three hybrids, the complex T-DNA locus was reduced efficiently to a single-copy locus. Upon segregation of the CRE recombinase gene, only the simplified T-DNA locus was found in the progeny, demonstrating DNA had been excised efficiently in the progenitor cells of the gametes. In the two transformants with an inverted T-DNA repeat, the T-DNA resolution was accompanied by at least a 10-fold enhanced transgene expression. Therefore, the resolution of complex loci to a single-copy T-DNA insert by the CRE/loxP recombination system can become a valuable method for the production of elite transgenic Arabidopsis thaliana plants that are less prone to gene silencing.     

Analysis of T-DNA-<Emphasis Type="Italic">Xa21</Emphasis> loci and bacterial blight resistance effects of the transgene <Emphasis Type="Italic">Xa21</Emphasis> in transgenic rice

The genetic loci and phenotypic effects of the transgene Xa21, a bacterial blight (BB) resistance gene cloned from rice, were investigated in transgenic rice produced through an Agrobacterium-mediated transformation system. The flanking sequences of integrated T-DNAs were isolated from Xa21 transgenic rice lines using thermal asymmetric interlaced PCR. Based on the analysis of 24 T-DNA- Xa21 flanking sequences, T-DNA loci in rice could be classified into three types: the typical T-DNA integration with the definite left and right borders, the T-DNA integration linked with the adjacent vector backbone sequences and the T-DNA integration involved in a complicated recombination in the flanking sequences. The T-DNA integration in rice was similar to that in dicotyledonous genomes but was significantly different from the integration produced through direct DNA transformation approaches. All three types of integrated transgene Xa21 could be stably inherited and expressed the BB resistance through derived generations in their respective transgenic lines. The flanking sequences of the typical T-DNA integration consisted of actual rice genomic DNA and could be used as probes to locate the transgene on the rice genetic map. A total of 15 different rice T-DNA flanking sequences were identified. They displayed restriction fragment length polymorphisms (RFLPs) between two rice varieties, ZYQ8 and JX17, and were mapped on rice chromosomes 1, 3, 4, 5, 7, 9, 10, 11 and 12, respectively, by using a double haploid population derived from a cross between ZYQ8 and JX17. The blast search and homology comparison of the rice T-DNA flanking sequences with the rice chromosome-anchored sequence database confirmed the RFLP mapping results. On the basis of genetic mapping of the T-DNA- Xa21 loci, the BB resistance effects of the transgene Xa21 at different chromosome locations were investigated using homozygous transgenic lines with only one copy of the transgene. Among the transgenic lines, no obvious position effects of the transgene Xa21 were observed. In addition, the BB resistance levels of the Xa21 transgenic plants with different transgene copy numbers and on different genetic backgrounds were also investigated. It was observed that genetic background (or genome) effects were more obvious than dosage effects and position effects on the BB resistance level of the transgenic plants.     

Transgenic indica Rice Variety Pusa Basmati 1 Constitutively Expressing a Rice Chitinase Gene Exhibits Enhanced Resistance to Rhizoctonia solani

Agrobacterium-mediated transformation of an elite indica rice variety, Pusa Basmati 1, was performed using LBA4404 (pSB1, pMKU-RF2) that harbours a rice chitinase gene (chi11) under the control of the maize ubiquitin (Ubi1) promoter-intron. Right border (gus) and left border (hph) flanking sequences and the transgene (chi11) in the middle of the T-DNA were used as probes in Southern analysis. Out of eleven independent T0 plants regenerated, three had single copy T-DNA insertions and eight had multiple T-DNA insertions. Nine T₀ plants carried the complete T-DNA with the chitinase transgene. Two T₀ plants did not carry chi11, though they had other T-DNA portions. Three plants harbouring single copy insertions and one plant harbouring two inserted copies were analyzed in detail. A segregation ratio of 3:1, reflecting T-DNA insertion at a single locus, was observed in the progeny of all the four T₀ plants. Northern and western blot analyses of T₁ plants revealed constitutive expression of chitinase at high levels. Bioassays of T₁ plants indicated enhanced resistance to the sheath blight pathogen, Rhizoctonia solani, in comparison to control plants. A homozygous transgenic line was established from one T₀ line, which exhibited the maximum resistance to R. solani.