Generation of Marker- and Backbone-Free Transgenic Potatoes by Site-Specific Recombination and a Bi-Functional Marker Gene in a Non-Regular One-Border Agrobacterium Transformation Vector

A binary vector, designated PROGMO, was constructed to assess the potential of the Zygosaccharomyces rouxii R/Rs recombination system for generating marker- and backbone-free transgenic potato (Solanum tuberosum) plants with high transgene expression and low copy number insertion. The PROGMO vector utilises a constitutively expressed plant-adapted R recombinase and a codA-nptII bi-functional, positive/negative selectable marker gene. It carries only the right border (RB) of T-DNA and consequently the whole plasmid will be inserted as one long T-DNA into the plant genome. The recognition sites (Rs) are located at such positions that recombinase enzyme activity will recombine and delete both the bi-functional marker genes as well as the backbone of the binary vector, leaving only the gene of interest flanked by a copy of Rs␣and RB. Efficiency of PROGMO transformation was tested by introduction of the GUS reporter gene into potato. It was shown that after 21 days of positive selection and using 300 mgl⁻¹ 5-fluorocytosine for negative selection, 29% of regenerated shoots carried only the GUS gene flanked by a copy of Rs and RB. The PROGMO vector approach is simple and might be widely applicable for the production of marker- and backbone-free transgenic plants of many crop species.     

The Tnt1 family member Retrosol copy number and structure disclose retrotransposon diversification in different <Emphasis Type="Italic">Solanum</Emphasis> species

Eukaryotic genome expansion/retraction caused by LTR-retrotransposon activity is dependent on the expression of full length copies to trigger efficient transposition and recombination-driven events. The Tnt1 family of retrotransposons has served as a model to evaluate the diversity among closely related elements within Solanaceae species and found that members of the family vary mainly in their U3 region of the long terminal repeats (LTRs). Recovery of a full length genomic copy of Retrosol was performed through a PCR-based approach from wild potato, Solanum oplocense. Further characterization focusing on both LTR sequences of the amplified copy allowed estimating an approximate insertion time at 2 million years ago thus supporting the occurrence of transposition cycles after genus divergence. Copy number of Tnt1-like elements in Solanum species were determined through genomic quantitative PCR whereby results sustain that Retrosol in Solanum species is a low copy number retrotransposon (1–4 copies) while Retrolyc1 has an intermediate copy number (38 copies) in S. peruvianum. Comparative analysis of retrotransposon content revealed no correlation between genome size or ploidy level and Retrosol copy number. The tetraploid cultivated potato with a cellular genome size of 1,715 Mbp harbours similar copy number per monoploid genome than other diploid Solanum species (613–884 Mbp). Conversely, S. peruvianum genome (1,125 Mbp) has a higher copy number. These results point towards a lineage specific dynamic flux regarding the history of amplification/activity of Tnt1-like elements in the genome of Solanum species. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Performance Evaluation of Kits for Bisulfite-Conversion of DNA from Tissues,Cell Lines,FFPE Tissues,Aspirates, Lavages,Effusions, Plasma,Serum, and Urine

DNA methylation analyses usually require a preceding bisulfite conversion of the DNA. The choice of an appropriate kit for a specific application should be based on the specific performance requirements with regard to the respective sample material. In this study, the performance of nine kits was evaluated: EpiTect Fast FFPE Bisulfite Kit, EpiTect Bisulfite Kit, EpiTect Fast DNA Bisulfite Kit (Qiagen), EZ DNA Methylation-Gold Kit, EZ DNA Methylation-Direct Kit, EZ DNA Methylation-Lightning Kit (Zymo Research), innuCONVERT Bisulfite All-In-One Kit, innuCONVERT Bisulfite Basic Kit, innuCONVERT Bisulfite Body Fluids Kit (Analytik Jena). The kit performance was compared with regard to DNA yield, DNA degradation, DNA purity, conversion efficiency, stability and handling using qPCR, UV, clone sequencing, HPLC, and agarose gel electrophoresis. All kits yielded highly pure DNA suitable for PCR analyses without PCR inhibition. Significantly higher yields were obtained when using the EZ DNA Methylation-Gold Kit and the innuCONVERT Bisulfite kits. Conversion efficiency ranged from 98.7% (EpiTect Bisulfite Kit) to 99.9% (EZ DNA Methylation-Direct Kit). The inappropriate conversion of methylated cytosines to thymines varied between 0.9% (innuCONVERT Bisulfite kits) and 2.7% (EZ DNA Methylation-Direct Kit). Time-to-result ranged from 131 min (innuCONVERT kits) to 402 min (EpiTect Bisulfite Kit). Hands-on-time was between 66 min (EZ DNA Methylation-Lightning Kit) and 104 min (EpiTect Fast FFPE and Fast DNA Bisulfite kits). Highest yields from formalin-fixed and paraffin-embedded (FFPE) tissue sections without prior extraction were obtained using the innuCONVERT Bisulfite All-In-One Kit while the EZ DNA Methylation-Direct Kit yielded DNA with only low PCR-amplifiability. The innuCONVERT Bisulfite All-In-One Kit exhibited the highest versatility regarding different input sample materials (extracted DNA, tissue, FFPE tissue, cell lines, urine sediment, and cellular fractions of bronchial aspirates, pleural effusions, ascites). The innuCONVERT Bisulfite Body Fluids Kit allowed for the analysis of 3 ml plasma, serum, ascites, pleural effusions and urine.     

Using real-time PCR to determine transgene copy number in wheat

Transgene copy number is usually determined by means of Southern blot analysis which can be time consuming and laborious. In this study, quantitative real-time PCR was developed to determine transgene copy number in transgenic wheat. A conserved wheat housekeeping gene,puroindoline-b, was used as an internal control to calculate transgene copy number. Estimated copy number in transgenic lines using real-time quantitative PCR was correlated with actual copy number based on Southern blot analysis. Real-time PCR can analyze hundreds of samples in a day, making it an efficient method for estimating copy number in transgenic wheat.     

Anthocyanin expression in marker free transgenic wheat and triticale embryos

Wheat and triticale plants were transformed by bombardment of isolated scutella with a genetic construct consisting of the two anthocyanin biosynthesis regulatory genes, C1 and Bperu, each under the control of the Ltp1 embryo-specific promoter. Transgenic plants were obtained in the absence of selective pressure and selectable marker gene at a transformation frequency of 0.93% and 1.55% in triticale and wheat, respectively. Initial screening of T₀ lines was performed by polymerase chain reaction (PCR), and further confirmation of PCR positives was done using real-time PCR and by phenotypic observation. In this study, quantitative real-time PCR (qRT-PCR) was developed to determine the transgene copy number in transgenic wheat and triticale. A conserved wheat housekeeping gene, puroindoline-b, was used as an internal control to calculate the transgene copy number in wheat and the SYBR green detection method with a standard curve, constructed on the basis of serially diluted plasmid, was used to calculate the transgene copy in triticale. Estimated transgene copies varied from 3 to 8 in wheat and 4 to 7 in triticale lines. The presence of anthocyanin regulatory genes, promoter, and termination sequences was detected in six wheat lines and four triticale lines. However, anthocyanin-pigmented embryos were only observed visually in mature T₁ seeds of two transgenic wheat lines and a single triticale line. Multisite insertion and reorganization of transgenes was likely the explanation for the failure of expression for the anthocyanin genes in the remaining wheat and triticale transgenic lines.     

Gene stability in transgenic aspen ( Populus ). I. Flanking DNA sequences and T-DNA structure

The stability of transgenes in the genome of transformed plants depends strongly on their correct physical integration into the host genome as well as on flanking target DNA sequences. For long-lived species like trees, however, no information is available so far concerning inactivation or loss of transgenes due to gene silencing or somatic genome rearrangement events. In this study, four independently transformed 35S-rolC transgenic hybrid aspen plants (Populus tremula L. × tremuloides Michx.), each harbouring one copy of the transgene, were investigated during continuous growth in the greenhouse. In one of these transgenic lines (Esch5:35S-rolC-##1) individuals frequently show phenotypic reversions, while in the remaining three lines (Esch5:35S-rolC-#3, -#5, -#16) the gene was essentially stable. Molecular analysis including PCR, Southern and Northern assays clearly showed that the transgene had been lost in the revertant tissue of the unstable line. Sequencing of T-DNA right and left borders, and flanking DNA regions, in all four transgenic aspen lines revealed no differences either in the type of flanking DNA (G-C to A-T ratio) or with respect to the presence of enhancers or MAR (matrix associated repeats)-like structures. Primers located within the left and right flanking regions in the three stable lines could be used to recover the target sites from the untransformed plants. This was not possible, however, with the unstable line, indicating that at least one flanking sequence does not derive from the plant target DNA but is of unknown origin. PCR using other primer pairs, and inverse PCR analysis, revealed an additional truncated T-DNA copy of 1050 nucleotides adjacent to the left border of the complete copy in this line. Sequencing of this truncated T-DNA revealed that it represented an inverted copy of part of the right half of the original construct. This special feature would allow the inverted repeat to pair with right border sequences of the complete copy. This would explain the frequently observed reversion resulting in transgene loss as due to intrachromosomal base-pairing leading to double-stranded loops of single-stranded DNA during mitotic cell divisions. Received: 9 June 1998 / Accepted: 6 October 1998     

利用重测序技术获取转基因植物T-DNA插入位点

T-DNA插入位点的获得对于植物功能基因组学研究及转基因植物的筛选鉴定非常重要,但是目前常用的方法如反向PCR、半随机引物PCR等,除了操作复杂、消耗时间长外,特异性较差,效率也很低。本研究利用全基因组重测序技术,将3份转基因材料基因组DNA打包后进行重测序,利用转基因载体序列作为参考序列进行比对分析,得到4个T-DNA插入位点。对3份转基因材料进行PCR和Southern blot验证分析,成功获得了3份转基因材料全部T-DNA插入位点,其中1份材料为2拷贝插入。本文利用重测序技术建立了一种简单、可靠、高效的获取转基因植物T-DNA插入位点的方法,以期为植物功能基因组学及转基因研究奠定基础。     

A simple qPCR-based method to detect correct insertion of homologous targeting vectors in murine ES cells

The identification of correctly targeted embryonic stem (ES) cell clones from among the large number of random integrants that result from most selection paradigms remains an important hurdle in the generation of animals bearing homologously targeted transgenes. Given the limitations inherent to Southern blotting and standard PCR, we utilized quantitative real-time polymerase chain reaction (qPCR) to rapidly identify murine ES cell clones containing insertions at the correct genomic locus. Importantly, this approach is useful for screening ES clones from conditional/insertional “knock-in” strategies in which there is no loss of genetic material. Simple validation avoids the generation of assays prone to false negative results. In this method, probe and primer sets that span an insertion site detect and quantify the unperturbed gene relative to an irrelevant reference gene, allowing ES cell clones to be screened for loss of detection of one copy of the gene (functional loss of homozygousity (LOH)) that occurs when the normal DNA is disrupted by the insertion event. Simply stated, detected gene copy number falls from two to one in correctly targeted clones. We have utilized such easily designed and validated qPCR LOH assays to rapidly and accurately identify insertions in multiple target sites (including the Lepr and mTOR loci) in murine ES cells, in order to generate transgenic animals.     

Efficient isolation and mapping of Arabidopsis thaliana T-DNA insert junctions by thermal asymmetric interlaced PCR

Thermal asymmetric interlaced (TAIL-) PCR is an efficient technique for amplifying insert ends from yeast artificial chromosome (YAC) and P1 clones. Highly specific amplification is achieved without resort to complex manipulations before or after PCR. The adaptation of this method for recovery and mapping of genomic sequences flanking T-DNA insertions in Arabidopsis thaliana is described. Insertion-specific products were amplified from 183 of 190 tested T-DNA insertion lines. Reconstruction experiments indicate that the technique can recover single-copy sequences from genomes as complex as common wheat (1.5 × 10¹⁰ bp). RFLPs were screened using 122 unique flanking sequence probes, and the insertion sites of 26 T-DNA transgenic lines were determined on an RFLP map. These lines, whose mapped T-DNA insertions confer hygromycin resistance, can be used for fine-scale mapping of linked phenotypic loci.     

Quantitative real-time PCR as a screening tool for estimating transgene copy number in WHISKERS™-derived transgenic maize

. Quantitative real-time PCR (qRT-PCR) was adapted to estimate transgene copy number in transgenic maize callus and plants. WHISKERS™-derived transgenic callus lines and plants were generated using two different gene constructs. These transgenic materials represented a range of copy number. A 'standard curve' was established by mixing plasmid DNA with non-transgenic genomic maize DNA using a calculated ratio of target gene to host genome size. 'Estimated' copy number in the callus lines and plants using qRT-PCR was correlated with the 'actual' copy number based on Southern blot analysis. The results indicated that there was a significant correlation between the two methods with both gene constructs. Thus, qRT-PCR represents an efficient means of estimating copy number in transgenic maize.     

Transgenic Sugarcane with a cry1Ac Gene Exhibited Better Phenotypic Traits and Enhanced Resistance against Sugarcane Borer

We developed sugarcane plants with improved resistance to the sugarcane borer, Diatraea saccharalis (F). An expression vector pGcry1Ac0229, harboring the cry1Ac gene and the selectable marker gene, bar, was constructed. This construct was introduced into the sugarcane cultivar FN15 by particle bombardment. Transformed plantlets were identified after selection with Phosphinothricin (PPT) and Basta. Plantlets were then screened by PCR based on the presence of cry1Ac and 14 cry1Ac positive plantlets were identified. Real-time quantitative PCR (RT-qPCR) revealed that the copy number of cry1Ac gene in the transgenic lines varied from 1 to 148. ELISA analysis showed that Cry1Ac protein levels in 7 transgenic lines ranged from 0.85 μg/FWg to 70.92 μg/FWg in leaves and 0.04 μg/FWg to 7.22 μg/FWg in stems, and negatively correlated to the rate of insect damage that ranged from 36.67% to 13.33%, respectively. Agronomic traits of six transgenic sugarcane lines with medium copy numbers were similar to the non-transgenic parental line. However, phenotype was poor in lines with high or low copy numbers. Compared to the non-transgenic control plants, all transgenic lines with medium copy numbers had relatively equal or lower sucrose yield and significantly improved sugarcane borer resistance, which lowered susceptibility to damage by insects. This suggests that the transgenic sugarcane lines harboring medium copy numbers of the cry1Ac gene may have significantly higher resistance to sugarcane borer but the sugarcane yield in these lines is similar to the non-transgenic control thus making them superior to the control lines.     

Relevance of BAC transgene copy number in mice: transgene copy number variation across multiple transgenic lines and correlations with transgene integrity and expression

Bacterial artificial chromosomes (BACs) are excellent tools for manipulating large DNA fragments and, as a result, are increasingly utilized to engineer transgenic mice by pronuclear injection. The demand for BAC transgenic mice underscores the need for careful inspection of BAC integrity and fidelity following transgenesis, which may be crucial for interpreting transgene function. Thus, it is imperative that reliable methods for assessing these parameters are available. However, there are limited data regarding whether BAC transgenes routinely integrate in the mouse genome as intact molecules, how BAC transgenes behave as they are passed through the germline across successive generations, and how variation in BAC transgene copy number relates to transgene expression. To address these questions, we used TaqMan real-time PCR to estimate BAC transgene copy number in BAC transgenic embryos and lines. Here we demonstrate the reproducibility of copy number quantification with this method and describe the variation in copy number across independent transgenic lines. In addition, polymorphic marker analysis suggests that the majority of BAC transgenic lines contain intact molecules. Notably, all lines containing multiple BAC copies also contain all BAC-specific markers. Three of 23 founders analyzed contained BAC transgenes integrated into more than one genomic location. Finally, we show increased BAC transgene copy number correlates with increased BAC transgene expression. In sum, our efforts have provided a reliable method for assaying BAC transgene integrity and fidelity, and data that should be useful for researchers using BACs as transgenic vectors.     

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.     

Evaluation of five commercial nucleic acid extraction kits for their ability to inactivate Bacillus anthracis spores and comparison of DNA yields from spores and spiked environmental samples

This study evaluated five commercial extraction kits for their ability to recover DNA from Bacillus anthracis spores and spiked environmental samples. The kits evaluated represent the major types of methodologies which are commercially available for DNA or total nucleic acid extraction, and included the ChargeSwitch gDNA Mini Bacteria Kit, NucliSens Isolation Kit, Puregene Genomic DNA Purification Kit, QIAamp DNA Blood Mini Kit, and the UltraClean Microbial DNA Isolation Kit. Extraction methods were performed using the spores of eight virulent strains of B. anthracis. Viability testing of nucleic acid extracts showed that the UltraClean kit was the most efficient at depleting samples of live B. anthracis spores. TaqMan real-time PCR analysis revealed that the NucliSens, QIAamp and UltraClean kits yielded the best level of detection from spore suspensions. Comparisons of processed samples from spiked swabs and three powder types indicated that DNA extraction using the UltraClean kit resulted in the most consistently positive results and the lowest limit of detection. This study demonstrated that different nucleic extraction methodologies, represented here by various commercial extraction kits, differ in their ability to inactivate live B. anthracis spores as well as DNA yield and purity. In addition, the extraction method used can influence the sensitivity of real-time PCR assays for B. anthracis.     

piggyBac转座子AgoPLE1.1在黑腹果蝇种系转化中的应用

[目的]通过检测黑腹果蝇 DDrosophiila melanogaster中piggyBac(PB)转座子AgoPLE1.1的转化活性,明确AgoPLE1.1开发为昆虫转基因载体的潜力.[方法]构建AgoPLE1.1转座酶辅助质粒pAgoHsp和带有红色荧光标记的供体质粒pXLAgo-PUbDsRed,辅助质粒和供体...     

Targeted gene suppression by RNA interference: an efficient method for production of high-amylose potato lines

Production of high-amylose potato lines can be achieved by inhibition of two genes coding for starch branching enzymes. The use of antisense technology for gene inhibition have yielded a low frequency of high-amylose lines that mostly was correlated with high numbers of integrated T-DNA copies. To investigate whether the production of high-amylose lines could be improved, RNA interference was used for gene inhibition of the genes Sbe1 and Sbe2. Two constructs with 100 bp segments (pHAS2) or 200 bp segments (pHAS3) of both branching enzyme genes were cloned as inverted repeats controlled by a potato granule-bound starch synthase promoter. The construct pHAS3 was shown to be very efficient, yielding high-amylose quality in more than 50% of the transgenic lines. An antisense construct, included in the study as a comparator, resulted in only 3% of the transgenic lines being of high-amylose type. Noticeable was also that pHAS3 yielded low T-DNA copy inserts with an average of 83% of backbone-free transgenic lines being single copy events.     

转MSTN干扰载体细胞株的获得及外源基因整合情况的研究

转基因细胞株的建立能够为转基因体细胞克隆技术奠定重要基础。该实验利用MSTN干扰载体,转染鲁西黄牛胎儿成纤维细胞,获得5个相应的转基因单克隆细胞株。采用Realtime PCR和高效热不对称互交式PCR（hiTAIL-PCR）技术检测细胞克隆中MSTN表达载体的拷贝数及其在牛基因组中的整合位点。结果表明,荧光定量PCR有效检测到5个细胞克隆中质粒的拷贝数分别为2.26±0.32、1.52±0.25、25.68±1.02、8.43±0.73和6.72±0.10。hiTAIL-PCR对整合位点的检测结果表明,质粒片段在插入到基因组的过程中进行了重组,其与基因组的结点处有2或4个共同的碱基序列。该研究探索MSTN干扰载体在牛胎儿成纤维细胞中的整合机制,以期获得遗传背景清楚的转基因细胞作为体细胞核移植的重要材料,为高产转基因肉牛新品种的培育提供重要的理论和实验基础。     

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.