Estimating number of transgene copies in transgenic rapeseed by real-time PCR assay with<Emphasis Type="Italic">HMG I/Y</Emphasis> as an endogenous reference gene

In transgenic plants, the number of transgene copies can greatly influence the level of expression and genetic stability of the target gene. Transgene copy numbers are estimated by Southern blot analysis, which is laborious and time-consuming, requires relatively large amounts of plant materials, and may involve hazardous radioisotopes. Here we report the development of a sensitive, convenient real-time PCR technique for estimating the number of transgene copies in transgenic rapeseed. This system uses TaqMan quantitative real-time PCR and comparison with a novel, confirmed single-copy endogenous reference gene, high-mobile-group protein I/Y (HMG I/Y), to determine the numbers of copies of exogenous β-glucuronidase (GUS) and neomycin phosphotransferase II (nptII) genes. TheGUS andnptII copy numbers in primary transformants (T₀) were calculated by comparing threshold cycle (C _T) values of theGUS andnptII genes with those of the internal standard,HMG I/Y. This method is more convenient and accurate than Southern blotting because the number of copies of the exogenous gene could be directly deduced by comparing itsC _T value to that of the single-copy endogenous gene in each sample. Unlike other similar procedures of real-time PCR assay, this method does not require identical amplification efficiencies between the PCR systems for target gene and endogenous reference gene, which can avoid the bias that may result from slight variations in amplification efficiencies between PCR systems of the target and endogenous reference genes.     

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.     

实时荧光定量PCR法检测转基因小鼠拷贝数

目的利用实时荧光定量PCR法鉴定转基因小鼠外源基因插入拷贝数。方法以TG-CARK转基因首见鼠为研究对象,选取小鼠的高度保守基因Fabpi为内参,利用绝对定量的实时荧光PCR法鉴定转基因小鼠拷贝数,并与传统的Southern blot方法的定量结果进行比较。结果实时定量PCR鉴定的转基因拷贝数与Southernblot法完全一致,三只TG-CARK首见小鼠的拷贝数分别为1,7,45。结论实时定量PCR技术具有高准确性、高稳定性、高通量和低成本的优点,是比传统杂交技术更好的鉴定小鼠转基因拷贝数的方法。     

Quantitative real-time PCR assay to detect transgene copy number in cotton (Gossypium hirsutum)

A TaqMan quantitative real-time PCR detection system was developed to examine transgene copy number in cotton. GhUBC1, a gene validated to be present as a single copy per haploid Gossypium hirsutum genome, was used as the endogenous reference to estimate copy number of GFP and selection marker NPTII in 28 T0 plants. This system was found to be more accurate than genomic Southern blot hybridization and could effectively tell homozygotes from heterozygotes in a T1 transgenic cotton population. Therefore it is suitable for efficient and cost effective early screening of transgenic seedlings and identifying transgene homozygotes in segregation populations.     

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.     

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.     

Real-time quantitative PCR-based system for determining transgene copy number in transgenic animals

In this paper, we describe a rapid and accurate real-time quantitative PCR-based system to determine transgene copy number in transgenic animals. We used the 2(-deltadeltaCt) method to analyze different transgenic lines without the requirement of a control sample previously determined by Southern blot analysis. To determine the transgene copy number in several mouse lines carrying a goat beta-Lactoglobulin transgene, we developed a TaqMan assay in which a goat genomic DNA sample was used as a calibrator. Moreover, we used the glucagon gene as a reference control because this gene is highly conserved between species and amplifies with the same efficiency and sensitivity in goat as in mouse. With this assay, we provide an alternative simple method to determine the transgene copy number, avoiding the traditional and tedious blotting techniques. The assay's discrimination ability from our results is of at least six copies and, similar to the limitations of the blotting techniques, the accuracy of the quantification diminishes when the transgene copy number is high.     

An evaluation of new and established methods to determine T‐DNA copy number and homozygosity in transgenic plants.

Stable transformation of plants is a powerful tool for hypothesis testing. A rapid and reliable evaluation method of the transgenic allele for copy number and homozygosity is vital in analysing these transformations. Here the suitability of Southern blot analysis, thermal asymmetric interlaced (TAIL‐)PCR, quantitative (q)PCR and digital droplet (dd)PCR to estimate T‐DNA copy number, locus complexity and homozygosity were compared in transgenic tobacco. Southern blot analysis and ddPCR on three generations of transgenic offspring with contrasting zygosity and copy number were entirely consistent, whereas TAIL‐PCR often underestimated copy number. qPCR deviated considerably from the Southern blot results and had lower precision and higher variability than ddPCR. Comparison of segregation analyses and ddPCR of T₁ progeny from 26 T₀ plants showed that at least 19% of the lines carried multiple T‐DNA insertions per locus, which can lead to unstable transgene expression. Segregation analyses failed to detect these multiple copies, presumably because of their close linkage. This shows the importance of routine T‐DNA copy number estimation. Based on our results, ddPCR is the most suitable method, because it is as reliable as Southern blot analysis yet much faster. A protocol for this application of ddPCR to large plant genomes is provided.     

Standard Addition Quantitative Real-Time PCR (SAQPCR): A Novel Approach for Determination of Transgene Copy Number Avoiding PCR Efficiency Estimation

Quantitative real-time polymerase chain reaction (qPCR) has been previously applied to estimate transgene copy number in transgenic plants. However, the results can be erroneous owing to inaccurate estimation of PCR efficiency. Here, a novel qPCR approach, named standard addition qPCR (SAQPCR), was devised to accurately determine transgene copy number without the necessity of obtaining PCR efficiency data. The procedures and the mathematical basis for the approach are described. A recombinant plasmid harboring both the internal reference gene and the integrated target gene was constructed to serve as the standard DNA. It was found that addition of suitable amounts of standard DNA to test samples did not affect PCR efficiency, and the guidance for selection of suitable cycle numbers for analysis was established. Samples from six individual T₀ tomato (Solanum lycopersicum) plants were analyzed by SAQPCR, and the results confirmed by Southern blot analysis. The approach produced accurate results and required only small amounts of plant tissue. It can be generally applied to analysis of different plants and transgenes. In addition, it can also be applied to zygosity analysis.     

Developmentally regulated site-specific marker gene excision in transgenic <Emphasis Type="Italic">B. napus</Emphasis> plants

We have developed a self-excision Cre-vector to remove marker genes from Brassica napus. In this vector cre recombinase gene and bar expression cassette were inserted between two lox sites in direct orientation. These lox-flanked sequences were placed between the seed-specific napin promoter and the gene of interest (vstI). Tissue-specific cre activation resulted in simultaneous excision of the recombinase and marker genes. The vector was introduced into B. napus by Agrobacterium-mediated transformation. F1 progeny of seven lines with single and multiple transgene insertions was subjected to segregation and molecular analysis. Marker-free plants could be detected and confirmed by PCR and Southern blot in all transgenic lines tested. The recombination efficiency expressed as a ratio of plants with complete gene excision to the total number of investigated plants varied from 13 to 81% dependent on the transgene copy number. Potential application of this system would be the establishment of marker-free transgenic plants in generatively propagated species.     

Analysis and stability of the Respiratory Syncytial Virus antigen in a T<Subscript>3</Subscript> generation of transgenic tomato plants

The integration, expression, and stability of the Respiratory Syncytial Virus (RSV)-F protein was analyzed in a T₃ generation of transgenic cherry tomato, Solanum lycopersicum L. cv. Swifty Belle, plants. Expression of the RSV-F antigen, under the control of the fruit-specific promoter E-8, was investigated in T₃ plants derived from a transgenic line, identified as #120. Transgene integration of the RSV-F gene in the T₃ generation was initially determined by polymerase chain reaction (PCR). PCR analysis from line 120-7-2 revealed that all T₃ plants were homozygous for the transgene; whereas, line 120-6-4 showed segregation for the transgene. Enzyme-linked immunosorbent assay (ELISA) was used to quantify levels of RSV-F protein in these plants, and protein levels ranged from 0–22 μg/g of fresh weight, with an average of ~3 μg/g fresh weight. Southern blot analysis of the highest expressing plants revealed presence of a single copy of the RSV-F transgene in these plants.     

High-throughput assessment of transgene copy number in sugarcane using real-time quantitative PCR

Accurate and timely detection of transgene copy number in sugarcane is currently hampered by the requirement to use Southern blotting, needing relatively large amounts of genomic DNA and, therefore, the continued growth and maintenance of bulky plants in containment glasshouses. In addition, the sugarcane genome is both polyploid and aneuploid, complicating the identification of appropriate genes for use as references in the development of a high-throughput method. Using bioinformatic techniques followed by in vitro testing, two genes that appear to occur once per base genome of sugarcane were identified. Using these genes as reference genes, a high-throughput assay employing RT-qPCR was developed and tested using a group of sugarcane plants that contained unknown numbers of copies of the nptII gene encoding kanamycin resistance. Using this assay, transgene copy numbers from 3 to more than 50 were identified. In comparison, Southern blotting accurately identified the number of transgene copies for one line and by inference for another, but was not able to provide an accurate estimation for transgenic lines containing numerous copies of the nptII gene. Using the reference genes identified in this study, a high-throughput assay for the determination of transgene copy number was developed and tested for sugarcane. This method requires much less input DNA, can be performed much earlier in the production of transgenic sugarcane plants and allows much more efficient assessment of numerous potentially transgenic lines than Southern blotting.     

Development of transgenic finger millet (<Emphasis Type="Italic">Eleusine coracana</Emphasis> (L.) Gaertn.) resistant to leaf blast disease

Finger millet plants conferring resistance to leaf blast disease have been developed by inserting a rice chitinase (chi11) gene through Agrobacterium-mediated transformation. Plasmid pHyg-Chi.11 harbouring the rice chitinase gene under the control of maize ubiquitin promoter was introduced into finger millet using Agrobacterium strain LBA4404 (pSB1). Transformed plants were selected and regenerated on hygromycin-supplemented medium. Transient expression of transgene was confirmed by GUS histochemical staining. The incorporation of rice chitinase gene in R₀ and R₁ progenies was confirmed by PCR and Southern blot analyses. Expression of chitinase gene in finger millet was confirmed by Western blot analysis with a barley chitinase antibody. A leaf blast assay was also performed by challenging the transgenic plants with spores of Pyricularia grisea. The frequency of transient expression was 16.3% to 19.3%. Stable frequency was 3.5% to 3.9%. Southern blot analysis confirmed the integration of 3.1 kb chitinase gene. Western blot analysis detected the presence of 35 kDa chitinase enzyme. Chitinase activity ranged from 19.4 to 24.8. In segregation analysis, the transgenic R₁ lines produced three resistant and one sensitive for hygromycin, confirming the normal Mendelian pattern of transgene segregation. Transgenic plants showed high level of resistance to leaf blast disease compared to control plants. This is the first study reporting the introduction of rice chitinase gene into finger millet for leaf blast resistance.     

Highly efficient transformation of the GFP and MAC12.2 genes into precocious trifoliate orange (Poncirus trifoliata [L.] Raf), a potential model genotype for functional genomics studies in Citrus

Precocious trifoliate orange (Poncirus trifoliata [L.] Raf), an extremely early flowering mutant of P. trifoliata, is an attractive model for functional genomics research in Citrus. A procedure for efficient regeneration and transformation of this genotype was developed by using green fluorescent protein (GFP) gene as visual marker and etiolated stem segments as explants. In vivo monitoring of GFP expression permitted a rapid and easy discrimination of transgenic shoots and escapes. Transformation efficiency was 20.7% and the transformants were identified by polymerase chain reaction (PCR) and Southern blot analysis. Moreover, the transgenic lines expressed variable amounts of the GFP gene as revealed by real-time PCR analysis. Fifteen transgenic plants flowered 18 months after transfer to the greenhouse and six of them set fruits. GFP expression was also observed in the transgenic flowers and fruits. To test the utility of this system for functional genomics studies, an Arabidopsis thaliana MAC12.2 gene with the potential to produce seedless fruits was introduced into this genotype, and the traits of the transgenic fruits were characterized. The successful transformation of this perennial woody genotype with extremely short juvenility will allow us to test the function of cloned genes in citrus, the improvement of which is hindered by a long juvenility period.     

Transgenic cotton expressing synthesized scorpion insect toxin AaHIT gene confers enhanced resistance to cotton bollworm (Heliothis armigera) larvae

A synthetic scorpion Hector Insect Toxin (AaHIT) gene, under the control of a CaMV35S promoter, was cloned into cotton via Agrobacterium tumefaciens-mediated transformation. Southern blot analyses indicated that integration of the transgene varied from one to more than three estimated copies per genome; seven homozygous transgenic lines with one copy of the T-DNA insert were then selected by PCR and Southern blot analysis. AaHIT expression was from 0.02 to 0.43% of total soluble protein determined by western blot. These homozygous transgenic lines killed larvae of cotton bollworm (Heliothis armigera) by 44–98%. The AaHIT gene could used therefore an alternative to Bt toxin and proteinase inhibitor genes for producing transgenic cotton crops with effective control of bollworm.     

Ovary-drip transformation: a simple method for directly generating vector- and marker-free transgenic maize (<Emphasis Type="Italic">Zea mays</Emphasis> L.) with a linear <Emphasis Type="Italic">GFP</Emphasis> cassette transformation

The presence of selectable marker genes and vector backbone sequences has affected the safe assessment of transgenic plants. In this study, the ovary-drip method for directly generating vector- and selectable marker-free transgenic plants was described, by which maize was transformed with a linear GFP cassette (Ubi-GFP-nos). The key features of this method center on the complete removal of the styles and the subsequent application of a DNA solution directly to the ovaries. The movement of the exogenous DNA was monitored using fluorescein isothiocyanate-labeled DNA, which showed that the time taken by the exogenous DNA to enter the ovaries was shortened compared to that of the pollen-tube pathway. This led to an improved transformation frequency of 3.38% compared to 0.86% for the pollen-tube pathway as determined by PCR analysis. The use of 0.05% surfactant Silwet L-77 + 5% sucrose as a transformation solution further increased the transformation frequency to 6.47%. Southern blot analysis showed that the transgenic plants had low transgene copy number and simple integration pattern. Green fluorescence was observed in roots and immature embryos of transgenic plants by fluorescence microscopy. Progeny analysis showed that GFP insertions were inherited in T₁ generation. The ovary-drip method would become a favorable choice for directly generating vector- and marker-free transgenic maize expressing functional genes of agronomic interest.     

Determination of Transgene Copy Number in Stably Transfected Mammalian Cells by PCR-Capillary Electrophoresis Assay

The quantitative determination of transgene copy number in stably transfected mammalian cells has been traditionally estimated by Southern blot analysis. Recently, other methods have become available for appraisal of gene copy number, such as real-time PCR. Herein we describe a new method based on a fluorescently labeled PCR, followed by capillary electrophoresis. We amplified our target gene (prothrombin) and the internal control originating from genomic DNA (18S rRNA) in the same PCR tube and calculated the mean peak height ratio of the target:control gene for every cell clone sample. With this approach we identified stably transfected cell clones bearing the same transgene copy number. The results of our assay were confirmed by real-time PCR. Our method proves to be fast, low-cost, and reproducible compared with traditionally used methods. This assay can be used as a rapid screening tool for the determination of gene copy number in gene expression experiments.