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。     

转基因水稻T—DNA侧翼序列的扩增与分析

利用现有的转抗白叶枯病基因Xa21的水稻材料,通过TAIL－PCR技术扩增出携带Xa21基因的T－DNA的侧翼序列,对24个有效扩增片段的序列分析结果表明,其中14个侧翼序列是水稻DNA,9个含载体主干序列,1个是外源基因Xa21片段,14个T－DNA侧翼的水稻DNA序列与直接转化法外源基因整合位点的基因组序列具有不同的特点,这些T－DNA在水稻染色体上整合后其两端序列的特点类似于在转基因双子叶植物中观察到的现象,在含主干序列的侧翼序列（37．5％,9／24）,中,载体主干序列是以不同的类型出现的。     

T—DNA转移机理

根癌农杆菌（Agrobacteriumtumefaciens）作、一种革兰氏阴性的土壤杆菌,于1907年发现它是植物致瘤的起因。植物细胞被侵染后,形成冠瘪瘪（crowngall）,冠＆瘤细胞可产生正常细胞所不能产生的冠瘦群（。Pines）,被农杆菌利用作为碳源和氨源。农杆菌侵染后从植物肿瘤细胞中摄取营养的边种现象,被称为“遗传寄生”（seneticcolonisatton）o经过持续不断的基础研究,直到1974年,发现在农杆菌中有一种环形的Ti质粒fie200kb）,Ti质粒上的一段T－DNA（Tra——fer［＞NA）可以插入植物基因组,引起细胞特性补文化、从此,人们试图利用…     

一种适于转基因水稻PCR检测的微量DNA快速提取法

对已报道的小麦基因组DNA快速提取方法的部分步骤进行了简化,在水稻上进行了尝试。结果表明,简化法提取的水稻基因组DNA完整性好,PCR扩增效果与试剂盒提取法无明显的差异,结果稳定可靠;而且整个提取过程操作简单、花费时间少,样品用量少,仅需5-10mg,适用于大规模转基因水稻的PCR检测。     

黄瓜Ri T—DNA转化根的植株再生

本文利用发根农杆菌感染黄瓜植体得到的转化根,在不同激素配比的分分培养基上培养,进行再生植株的诱导试验,结果表明,ＮＡＡ和ＢＡ的合适配比,有利于黄瓜植株的再生,转化根及其再生植株检测到冠瘿碱的存在,说明农杆菌Ｒｉ质粒的Ｔ－ＤＮＡ已转移到黄瓜基因组中。     

一种基于PCR技术鉴定单拷贝转基因烟草的方法

为了鉴定携带单拷贝外源基因的转基因烟草植株,以烟草核基因组上已知的单拷贝内源基因（RNR2）为内参,转基因烟草植株基因组DNA为模板,在同一PCR反应体系中扩增内源基因（RNR2）和外源目的基因（NPTⅡ）。反应产物在琼脂糖凝胶上电泳,获得了预期大小的两条特异性扩增条带。经ImageJ软件捕捉分析两条目的条带的灰度比,当T1代转基因烟草植株中外源基因与内源基因的扩增条带灰度比为1时,所检测植株即为单拷贝外源基因的转基因烟草植株。孟德尔经典遗传学方法证实了上述检测结果高度可信。     

利用微波炉快速制备水稻基因组DNA PCR模板

建立了利用微波炉法快速制备水稻基因组DNA PCR模板的程序,成功地从水稻基因组扩增到了相应基因。     

转基因番木瓜基因组DNA的快速制备和PCR检测方法

转基因番木瓜检测中,模板DNA的制备是关键一步.为了提高检测效率,建立快速制备番木瓜样品基因组DNA和PCR检测方法十分重要.建立了番木瓜基因组DNA的快速制备方法,包括样品准备、制备缓冲液匀浆和稀释上清.在完成不同番木瓜样品的基因组DNA快速制备后,对获得的DNA进行PCR检测验证.普通PCR验证结果显示,本方法制备...     

利用竞争性PCR筛选无标记Xa21转基因水稻

PCR是一种简单、迅速、灵敏的检测方法,但假阳性与假阴性却影响了它在常规应用中的准确性。本研究利用竞争性PCR解决无标记Xa21转基因水稻PCR检测中的假阳性与假阴性问题。标记基因潮霉素基因(Hygromycin phosphotransferase,hpt)的竞争模板是外加的日本晴hpt转基因植株基因组DNA,抗白叶枯病基因Xa21的竞争模板是待测水稻内源的位于第11染色体上的Xa21同源基因序列。利用这一方法对双右边界T-DNA载体转化产生的转基因T1代植株进行分析,可以有效地减少或排除假阳性或假阴性样品,选出真正的转基因阳性植株。与常规PCR相比竞争性PCR提高了无标记Xa21转基因植株筛选的准确性。对获得的无标记Xa21转基因植株进行白叶枯抗病鉴定与潮霉素抗性鉴定证实了该方法的可靠性。     

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].     

An alternative inverse PCR (IPCR) method to amplify DNA sequences flanking Tn5 transposon insertions

We have developed an alternative method to amplify DNA sequences flanking Tn5 transposon insertions. This method relies on the identical sequences of inverted terminal repeats, located at the 5' and 3' ends of Tn5, to determine the location and orientation of a transposon insertion within a restriction endonuclease fragment. From this information, PCR primers can be designed to selectively amplify by inverse PCR the DNA flanking one side of the transposon. This method avoids the problem of amplifying or cloning long sequences flanking Tn5. To demonstrate the applicability of this method, we generated Tn5 transposon mutants of Pseudomonas abietaniphila BKME-9 which no longer grew on dehydroabietic acid (DhA). The flanking sequence of one of the mutant (strain BKME-941) which accumulated 7-oxoDhA, was amplified.     

实时荧光定量PCR(TaqMan)法测定外源基因的拷贝数

实时荧光定量PCR是近年新兴的一项技术,因其快速、方便、便宜,需要DNA样品量少,无需放射性检测等优点被广泛应用于基因的定量分析。该文就实时荧光定量PCR(TaqMan)技术的发展、基本原理及测定外源基因拷贝数的技术流程做一介绍。     

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.     

Construction of a deletion library using a mixture of 5'-truncated primers for inverse PCR (IPCR).

A quick in vitro mutagenesis method for the construction of nested deletion libraries was developed. Many deletions can be obtained in a single inverse PCR (IPCR) by replacing one of the two primers with a mixture of 5'-truncated oligodeoxynucleotides. Since chemical DNA synthesis proceeds from the 3'to the 5'end, such a mixture of 5'-truncated oligodeoxynucleotides can easily be obtained in a single automated DNA synthesis under reduced coupling efficiency. This deletion mutagenesis method yields many different deletions in a defined short DNA segment and is, therefore, best suited for a deletion analysis at base pair level. Applications might include functional analysis of regulatory DNA segments and protein engineering work that requires libraries for the expression of N-terminal, C-terminal or internal truncated proteins as well as fusion proteins having different splice sites.     

Use of real-time PCR for determining copy number and zygosity in transgenic plants

This review examines how real-time PCR can be used to determine copy number and zygosity in transgenic plants. Distinguishing between plants that harbor one and two copies of a transgene or are hemizygous and homozygous requires the ability to routinely distinguish twofold differences, a detection difference which approaches the resolution of PCR-based quantification methods. After explaining the basic principles, especially the threshold cycle (Ct value) as the basic measuring unit in real-time PCR, we introduce three quantitation methods currently in use. While the absolute and relative standard curve approaches are qualitative methods that distinguish high-copy from low-copy transformants, the comparative ( ) method with double-dye oligonucleotides (TaqMan probes) is able to detect twofold differences. In order to obtain reliable results, Ct values for an amplicon should be below 25 and the standard deviation below 0.3. Although real-time PCR can deliver exact copy number determinations, the procedure is not fail-safe. Therefore, real-time PCR should to be viewed as complementary to—rather than as a replacement of—other methods such as Southern analysis, but it is particularly useful as a preliminary screening tool for estimating copy numbers of a large number of transformants.     

Evaluation of the rrn operon copy number in Bifidobacterium using real-time PCR

AIMS: A real-time PCR-based method was developed to evaluate the Bifidobacterium rRNA operon copy number. As a result of their repetitive nature, rRNA operons are very suitable targets for chromosomal integration of heterologous genes. METHODS AND RESULTS: The rrn operon multiplicity per chromosome was determined by real-time PCR quantification of the 16S rRNA amplicons obtained from genomic DNA. The values obtained in several bifidobacterial strains of human origin ranged from 1 to 5. The reliability of the method developed was confirmed by Southern hybridization technique. CONCLUSIONS: In the Bifidobacterium genus the rrn operon copies showed variability at species and strain level. The identification of Bifidobacterium strains with high rRNA multiplicity allowed the selection of potential hosts for chromosomal integration. SIGNIFICANCE AND IMPACT OF THE STUDY: The methodology here proposed represents a rapid, reliable and sensitive new tool for the quantification of rrn operon copy number in bacteria.     

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.     

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.