抗草甘膦转基因大豆PCR检测及问题探讨

转基因植物的检测具有重要的意义。用抗草甘膦转基因大豆中的外源CaMV35S启动子、CP4 EPSPS和巢式PCR引物,应用PCR方法,从中扩增出预期大小的DNA片段。将扩增产物回收后测序,经同源性分析扩增产物为CaMV35S启动子和CP4 EPSPS的一部分序列。与常规PCR相比,巢式PCR在检测转基因大豆中具有更高的特异性。讨论了PCR检测过程中假阴性和假阳性的原因。     

转基因抗草甘膦油菜的检测方法

目的:建立检测田间转基因抗草甘膦油菜的方法。方法:用CTAB法提取DNA,经PCR分别扩增内参基因BnACCg8,及抗草甘膦外源基因CP4-EPSPS、FMV 35S启动子和E9 3’终止子等4种基因的片段,以琼脂糖凝胶电泳对扩增产物进行分析比对。结果:抗草甘膦油菜中分别扩增出与外源基因FMV 35S启动子、E9 3’终止子和CP4-EPSPS大小一致的片段。结论:该方法能有效地用于转基因抗草甘膦油菜的检测。     

PCR技术定性检测转基因大豆方法的建立与研究

以转基因大豆(RRS品系)为材料,采用PCR技术,通过特异性引物和探针,对转基因大豆中的内源性基因Lectin和外源基因35S启动子、NOS终止子及CP4-EPSPS进行定性检测,旨在建立一种简单、快速、高效的检测方法,并将该方法用于我国进口自美国大豆实施检测,以评判是否为转基因大豆,为我国的商业谈判提供依据,同时也可满足百姓的知情权。     

PCR对转基因玉米CBH351品系的鉴定检测

成功建立了转基因玉米CBH351（Starlink^TM)的筛选和品系鉴定检测的PCR方法,该方法根据玉米自身IVR基因作为内源特异参照基因来检查模板DNA提取的质量,避免了假阴性结果,设计检测CaMV35S启动子的引物扩增195bp,来对转基因玉米进行筛选检测;并进一步设计转基因玉米CBH351（StarlinkTM)品系转化质粒图谱中CaMV35S启动子和Cry9C边界位置基因特异性引物扩增170bp,以及目标基因Cry9C的右端与CaMV35S终止子的左端边界位置基因特异性引物扩增171bp,以此来鉴定检测CBH351（StarlinkTM)的品系。     

转基因烟草检测技术研究

本研究建立了转基因烟草常用调控基因35S启动子和nos终止子,标记基因npt-II和目的基因TMV－CP的PCR检测技术,并用轻构建的pUC18质粒提纯的35S启动子和nos终止子基因经地高辛标记后制成了基因探针,建立了检测35S启动子和os终止子的分子杂交技术,杂交试验证明,PCR扩增的35S启动子和nos终止子为特异性扩增产物,此项检测技术具有快速,特异,敏感,经济以及可重复性强等优点。     

Chelex-100快速提取用于转基因检测DNA模板的研究

目的:建立从转基因作物中快速提取DNA的方法.方法 :采用Chelex-100法提取抗草甘膦大豆和非转基因大豆、转基因抗虫玉米Bt176和非转基因玉米中的DNA,使用PCR扩增大豆和玉米的内源基因(Lectin,zSSⅡb)及外源特异性序列(CaMV35S,Bt176)评价提取核酸的质量.结果 :Chelex-100法能够快速在1h之内从大豆和玉米中提取DNA,所提取的DNA可以直接用于PCR扩增反应,PCR扩增产物电泳条带清晰,转基因抗草甘膦大豆样品和转基因抗虫玉米Bt176检测均出现强阳性结果.结论 :Chelex-100法提取DNA可以作为转基因检测的模板,该方法具有经济、简便、快速的特点,适合于转基因检测工作.     

大豆油中转基因成分的Nested PCR和Semi-nested PCR检测方法研究

对大豆油中DNA提取方法进行了研究,结果表明CTAB、SDS和Wizard试剂盒提取大豆油DNA均具有良好的效果。利用nested PCR和semi—nested PCR检测大豆（Roundup Ready）油中的转基因成分发现,该方法能够检测到大豆原油中的Lectin基因（112bp）、CaMV35S基因（147bP）和CP4-EPSPS基因（205bp）,检测灵敏度达到10^-6ng／μl;但该方法未能从人豆成品油（一级）中扩增到上述基因,当中的转基因成分DNA含量低于10^-12ng／μl。     

核酸层析法转基因快速检测体系的建立及应用

随着我国转基因研究及产业化进程提速,转基因检测的重要性日益凸显,因而快速、高效的分子检测新方法的研发具有重要的生产实践及科研意义。在转基因检测中,常规PCR技术具有检测范围广的特点,但较为费时费力,且对实验条件要求较高;而胶体金蛋白试纸法检测方便、快捷,但可检范围窄。基于此,建立了一套基于核酸层析法快速转基因检测的方法体系。将经液氨研磨后的样品通过一管法提取DNA后直接进行PCR扩增,再将PCR扩增产物滴加到胶体金检测卡上,通过直接观察胶体金卡条显色状况进行结果判别。此方法最终检验出玉米内参基因ZSSⅡB及Zein、大豆内参基因SPS、水稻内参基因Lectin,转基因元件启动子CaMV35S及终止子NOS,以及抗虫基因Cry1Ab/1Ac、抗除草剂基因Bar、Pat、CP4-EPSPS及选择标记基因NPTⅡ、Pmi等外源基因;并成功检出特异性转基因事件Mir604及Bt11。研究获得的核酸层析检测方法具有灵敏度高、省时省力且对检测条件要求低等优点,集PCR法与蛋白试纸检测法二者优势于一身,可广泛应用于转基因产品的精确快速检测,为我国转基因生物安全监管提供了良好的技术支撑。     

高灵敏度电化学发光PCR方法检测花椰菜花叶病毒35 S启动子

大多数转基因植物中使用花椰菜花叶病毒(cauliflower mosaic virus,CaMV)35 S作为启动子,因此可通过检测该启动子来判断植物样品中是否含有转基因成分。实验将高灵敏度电化学发光PCR方法用于检测转基因烟草中的CaMV35 S启动子,将该启动子的PCR产物与生物素标记的探针杂交,可以起到特异性筛选产物的作用;与发光标记物——三联吡啶钌标记的探针杂交,从而实现电化学发光检测。两种探针同时与待测样品的PCR产物进行杂交,进一步对样品进行特异性筛选,从而提高了检测的准确性,避免了假阳性结果的产生。实验结果表明:该法可以准确的区分待测样品中是否含有35 S启动子,从而区别转基因烟草和非转基因烟草。电化学发光PCR方法灵敏度高,可靠性强,操作简便,结果准确,有望成为一种高效的转基因植物检测方法。     

用PCR和SDS-PAGE两种方法对转基因大豆的检测

采用PCR和SDS-PAGE电泳两种方法对转基因大豆(美国)和非转基因大豆(国内3个不同样品)进行了检测．结果显示：转基因大豆可以检测出195bp的花椰菜花叶病毒启动子(CaMV35S)序列片段和320bp的抗草甘膦基因(EPSPS)片段;SDS-PAGE蛋白质电泳中有一约40kDa的蛋白带出现;而非转基因的3个国内大豆品种中均没有CaMV35S启动子序列片段和抗草甘膦基因片段,SDS-PAGE蛋白质电泳检测也没有发现转基因大豆中存在的40kDa的蛋白带．     

膨化对转基因豆粕CP4-EPSPS蛋白的影响

旨在研究转基因豆粕经挤压膨化后外源蛋白的变化规律.以CP4-EPSPS多克隆抗体和转基因含量为2％的大豆标准品作为材料,建立ELISA法定量检测抗草甘膦转基因大豆CP4-EPSPS蛋白的方法.结果表明,膨化豆粕中外源蛋白含量随着温度和含水率的升高逐渐降低,ELISA法检测低限达到0.25％,可以定量检测经过加工的转基因豆粕.     

Isolation of two highly active soybean (<Emphasis Type="Italic">Glycine max</Emphasis> (L.) Merr.) promoters and their characterization using a new automated image collection and analysis system

A novel automated image collection and analysis system was used to compare two new soybean (Glycine max (L.) Merr.) promoters with the cauliflower mosaic virus 35S (CaMV35S) promoter, which was used as an expression standard. For expression comparisons, various permutations of a soybean polyubiquitin (Gmubi) promoter, a soybean heat shock protein 90-like (GmHSP90L) promoter and the CaMV35S promoter were placed upstream of a green fluorescent protein (gfp) gene. DNA constructs were introduced via particle bombardment into excised cotyledons of germinating lima bean (Phaseolus lunatus L.) seeds, which were arranged in Petri dishes for automated image capture and image analysis. The automated system allowed monitoring and quantification of gfp gene expression in the same piece of tissue over time. The Gmubi promoter, with its intronic region intact, showed the highest expression that was over five times stronger than the CaMV35S promoter. When an intronic region was removed from the Gmubi promoter, GFP expression was reduced, but was still over two times greater than with the CaMV35S promoter. The full-length soybean GmHSP90L promoter was four times stronger than the CaMV35S promoter. Truncation of the GmHSP90L promoter resulted in stepwise decreases in promoter strength, which appear to correspond to removal of regulatory elements. Automated image capture and analysis allowed the rapid and efficient evaluation of these new promoters. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

不同调控序列控制下的GUS基因在水稻和毛白杨愈伤组织中的瞬时表达

用CaMV35S启动子、玉米Ubil启动子、TMVΩ增强子(Ω序列)以及拟南芥18S rRNA基因同源序列构建的6种GUS基因表达载体分别转化水稻和毛白杨愈伤组织,研究不同调控序列对外源基因表达的调控作用.结果表明:(1)在水稻中,以独立Ubil启动子驱动下的GUS基因表达水平为最高,CaMV35S启动子附加18SrRNA基因同源序列调控下的GUS基因为最低.而在毛白杨中,则呈相反趋势;(2)在水稻中,CaMV35S-Ubil复合启动子的表达活性比独立CaMV35S启动子提高了近1.5倍.而在毛白杨中,前者比后者的低;(3)Ubil启动子附加Ω序列,使GUS基因在毛白杨中的表达水平提高一倍以上.但CaMV35S-Ubil复合启动子附加Ω序列,对GUS基因在毛白杨及水稻愈伤组织中的表达活性均没有明显的增强作用.     

Evaluation of constitutive viral promoters in transgenic soybean roots and nodules

The efficiency of beta-glucuronidase (GUS) expression was evaluated with five viral promoters to identify the most suitable promoter or promoters for use in soybean hairy roots, including applications to study the symbiotic interaction with Bradyrhizobium japonicum. Levels of GUS activity were fluorimetrically and histochemically assayed when the GUS (uidA) gene was driven by the Cauliflower mosaic virus (CaMV) 35S promoter and enhanced 35S (E35S) promoter, the Cassava vein mosaic virus (CsVMV) promoter, the Figwort mosaic virus (FMV) promoter, and the Strawberry vein banding virus (SVBV2) promoter. We demonstrate that GUS activity was highest when driven by the FMV promoter and that the promoter activity of 35S and SVBV2 was significantly lower than that of the CsVMV and E35S promoters when tested in soybean hairy roots. In mature soybean root nodules, strong GUS activity was evident when the FMV, 35S, and CsVMV promoters were used. These results indicate that the FMV promoter facilitates the strong expression of target genes in soybean hairy roots and root nodules.     

Electroporation and PEG delivery of DNA into maize microspores

Summary The ability to deliver and detect reporter gene activity in maize microspores was tested. Tested expression vectors contained the chloramphenicol acetyl transferase (CAT) gene and one of the following promoter-intron combinations: 1) cauliflower mosaic virus (CaMV 35S), 2) CaMV 35S + maize alcohol dehydrogenase 1 intron 6 (Adh1-I6), 3) maize alcohol dehydrogenase 1 + intron 1 (Adh1-I1), or 4) maize ubiquitin 1 + intron 1 (Ubiq 1-I1) promoter + intron. The expression vectors were delivered into maize microspores using electroporation or polyethylene glycol (PEG). Both methods were effective for delivering free DNA into microspores. Although all four promoters were active in maize protoplasts, only two promoters were active in maize microspores. The CaMV 35S and the Adh1 promoters did not promote gene expression in maize microspore. The CaMV 35S + Adh1-I6 and Ubiq1-I1 promoters produced high levels of CAT activity in maize microspores.     

Identification of genetically modified vegetable sources in food and feed using hydrogel oligonucleotide microchip

A method of multiplex polymerase chain reaction (PCR) followed by the hybridization on a hydrogel oligonucleotide biochip was developed for simultaneous identification of ten different transgenic elements of plant DNA in feed and food products. The biochip contained 22 immobilized probes intended for (i) detection of plant DNA; (ii) plant species determination (soybean, maize, potato, rice); (iii) identification of transgenic elements, including 35S CaMV, 35S FMV, rice actine gene promoters, nos, 35S CaMV, ocs, pea rbcS1 gene terminators, and bar, gus, nptII marker genes. The limit of detection was 0.5% of genetically modified (GM) soybean and maize in analyzed samples. Identification of transgenic DNA in food and feed products using either the developed approach or real-time PCR led to virtually identical results. The assay can be used for selection of GM samples by screening food and feed products for subsequent quantitative determination of the GM component based on the identified transgene.     

Identification of plant-derived genetically modified organisms in food and feed using a hydrogel oligonucleotide microchip

A method of multiplex polymerase chain reaction (PCR) followed by hybridization on a hydrogel oligonucleotide biochip was developed for simultaneous identification of ten different transgenic elements of plant DNA in food and feed products. The biochip contained 22 immobilized oligonucleotide probes that were intended for (1) detection of plant DNA, (2) determination of plant species (soybean, maize, potato, and rice), and (3) identification of transgenic elements, including sequences of 35S CaMV, 35S FMV, rice actin gene promoters, nos, 35S CaMV, ocs, pea rbcS1 gene terminators, and bar, gus, and nptII marker genes. The limit of detection was 0.5% for genetically modified (GM) soybean and maize in the analyzed samples. The tests on food and feed products using the developed approach and real-time PCR showed full agreement in determination of transgenic DNA in the samples. The proposed assay can be used for selection of GM samples by screening food and feed products for subsequent quantitative determination of GM component based on the identified transgene.