利用子房滴注法获得无载体骨架序列和选择标记的转基因玉米

转基因植物中的载体骨架序列和选择标记基因是引起生物安全性争论的根本原因, 最直接、最有效的解决方法是在转化过程中不使用载体骨架序列和选择标记基因。本研究建立并优化了玉米子房滴注转化法, 其操作要点是将DNA转化溶液直接滴加在完全去除花柱的子房上。利用子房滴注法将无载体骨架序列和选择标记的线性GFP基因表达框转化玉米。PCR结果表明: 适合子房滴注法转化的玉米品种为9818, 最佳转化时间为授粉后18~20 h, 在此条件下得到最高的PCR阳性率, 为3.01%; Southern blotting结果表明外源基因的整合方式简单(1~2条杂交带); RT-PCR结果表明转基因植株中GFP基因能够在RNA水平上正常表达; 在转基因植株的根和幼胚中观察到GFP表达。     

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.     

Transformation of wheat with the HMW-GS 1Bx14 gene without markers

High molecular weight (HMW) glutenin polypeptides are critical contributors to the visco/elastic properties responsible for the processing characteristics and utilizations of wheat flour. In order to improve bread making quality of flour and produce transgenic plants free of selectable markers, a linear DNA construct consisting of a minimal expression cassette with the HMW-GS 1Bx14 gene was transformed into wheat cultivar Mianyang 19 by microprojectile bombardment. The transformants were selected by PCR instead of herbicidal markers. Seven transgenic plants were identified from a total of 1219 transformants, yielding a transformation frequency of 0.28%. An SDS-PAGE analysis confirmed that the 1Bx14 gene was expressed in three T1 seeds of the transgenic plants. Our results demonstrated that it is feasible to obtain marker-free transformants using the linear-expression-cassette-transformation approach coupled with PCR selection.     

Transformation of wheat with the HMW-GS <Emphasis Type="Italic">1Bx14</Emphasis> gene without markers

High molecular weight (HMW) glutenin polypeptides are critical contributors to the visco/elastic properties responsible for the processing characteristics and utilizations of wheat flour. In order to improve bread making quality of flour and produce transgenic plants free of selectable markers, a linear DNA construct consisting of a minimal expression cassette with the HMW-GS 1Bx14 gene was transformed into wheat cultivar Mianyang19 by microprojectile bombardment. The transform ants were selected by PCR instead of herbicidal markers. Seven transgenic plants were identified from a total of 1219 transformants, yielding a transformation frequency of 0.28%. An SDS-PAGE analysis confirmed that the 1Bx14 gene was expressed in three T1 seeds of the transgenic plants. Our results demonstrated that it is feasible to obtain marker-free trans-formants using the linear-expression-cassette-transformation approach coupled with PCR selection.     

Green fluorescent protein as a visual selection marker for coffee transformation

The green fluorescent protein (GFP) was used as a visual selectable marker to produce transgenic coffee (Coffea canephora) plants following Agrobacterium-mediated transformation. The binary vector pBECKS 2000.7 containing synthetic gene for GFP (sgfp) S65T and the hygromycin phosphotransferase gene hph both controlled by 35S cauliflower mosaic virus CaMV35S promoters was used for transformation. Embryogenic cultures were initiated from hypocotyls and cotyledon leaves of in vitro grown seedlings and used as target material. Selection of transformed tissue was carried out using GFP visual selection as the sole screen or in combination with a low level of antibiotics (hygromycin 10 mg/L), and the efficiency was compared with antibiotics selection alone (hygromycin 30 mg/L). GFP selection reduced the time for transformed somatic embryos formation from 18 weeks on a hygromycin (30 mg/L) antibiotics containing medium to 8 weeks. Moreover, visual selection of GFP combined with low level of antibiotics selection improved the transformation efficiency and increased the number of transformed coffee plants compared to selection in the presence of antibiotics. Molecular analysis confirmed the presence of the sgfp-S65T coding region in the regenerated plants. Visual screening of transformed cells using GFP by Agrobacterium-mediated transformation techniques was found to be efficient and therefore has the potential for development of selectable marker-free transgenic coffee plants.     

选择标记可去除的植物高效表达载体的构建

在常用的植物组成型表达载体pBI121的选择标记基因NPTII两侧插入同向的lox位点并用多克隆位点(MCS)取代了GUS基因序列,构建了NPTII基因可被去除的和可插入目的基因的通用植物表达载体pBI121-lox-MCS。替换pBI121-lox-MCS中驱动目的基因表达的35S启动子,可构建成一系列具有其他表达特性的植物表达载体,如本文描述的韧皮部特异表达载体pBdENP-lox-MCS。为方便地筛选去除选择标记基因的转基因植物,还构建了绿色荧光蛋白(GFP)表达框与NPTII表达框连锁的pBI121-gfp-lox-MCS载体。上述植物表达载体可广泛应用于培育选择标记可去除的转基因植物。     

Asexual production of selectable marker-free transgenic woody plants, vegetatively propagated species

We describe here a practical system for generating selectable marker-free transgenic woody plants independent of sexual crossing. We previously reported that the GST-MAT vector system could produce marker-free transgenic tobacco plants containing a single-copy transgene at high frequency. The GST-MAT vector system consists of a DNA excision cassette of the R/RS site-specific recombination system from Zygosaccharomyces rouxii into which the isopentenyltransferase gene from Agrobacterium tumefaciens has been inserted. In this study, we applied this new GST-MAT vector to hybrid aspen (Populus Sieboldii X Populus grandidentata), a model of vegetatively propagated plant species, to produce selectable marker-free transgenic woody plants. In the new GST-MAT vector, the chimeric ipt gene fused with a light-inducible rbcS promoter efficiently produced transgenic ipt-shooty with GUS activity from 38.0% of infected stems. Upon excision of the R and ipt genes between RS sites, regulated by the inducible promoter of the maize glutathione-S-transferase (GST-II-27) gene, 3 (21.4%) transgenic hybrid aspen plants with marker-free and normal phenotype were generated from 14 ipt-shooty lines within 2 months after cutting induction. These results suggest that the MAT-vector system might be useful for removing a selectable marker gene independent of sexual crossing in vegetatively propagated species.     

农杆菌介导的半夏凝集素基因(Pinellia Ternate Agglutinin Gene,pta)对小麦的遗传转化及鉴定

以甘肃主要推广春小麦品种陇春22幼胚为转基因受体材料,建立了农杆菌介导的小麦遗传转化体系。以预培养4天的幼胚愈伤组织为受体,C58c1农杆菌菌株为供体,将含有半夏凝集素基因的重组质粒pBIpta转入了小麦,经G418 25 mg/L抗性筛选、PCR检测和荧光定量PCR检测共获得转基因植株3株,外源基因的插入拷贝数分别为2、1、3。同时对转基因小麦的T₁代植株进行了PCR检测和抗虫性分析,表明半夏凝集素基因在转基因植株的后代中得到了遗传并有一定的抗蚜虫作用。     

用绿色荧光蛋白监测转基因植物中选择标记基因的消除

绿色荧光蛋白(GFP)可直接进行活体观察,它的这个优点可被用于监测转基因植物中选择标记基因的消除。为此,构建了植物表达载体pGNG,将绿色荧光蛋白基因(gfp)和卡那霉素抗性基因表达盒(NosP-nptll-NosT)一起克隆在两个同向的lox位点间,在第一个lox位点上游置有CaMV 35S启动子以驱动GFP表达,第二个lox位点下游置有不含启动子的大肠杆菌β-葡萄糖醛酸酶(GUS)基因。首先在含卡那霉素(Kan)的培养基上筛选出转pGNG的烟草,借助绿色荧光可容易地检出表达GFP的转化体。然后用另一转化载体pCambia1300Cre二次转化表达GFP的转基因植物,利用另一选择标记基因潮霉素抗性基因(hpt)进行筛选,在获得的再生植株中,Cre重组酶的表达消除了转化体中两lox位点间的gfp和nptll。实验结果表明可借助GFP荧光的消失,快速选出nptII被消除的二次转化体,同时GUS(作为目的蛋白) 在CaMV 35S启动子驱动下获得表达。最后利用后代的分离将hpt和cre除去。     

三个方便实用的植物表达载体构建与验证

为满足植物功能基因组学研究及转基因安全性需要,本研究根据一些国内外引进或商业化的植物表达载体及其相关元件,构建了3个适合于植物,尤其是单子叶植物转化的表达载体,即p AH006、p WMB022和p WMB025。p AH006载体包含由玉米泛素ubi启动子调控的GUS基因和bar基因的完整T-DNA区域,此区段能够被酶切回收,可用于单子叶植物农杆菌介导转化效率评价及基因枪介导线状DNA转化效果研究;p WMB022载体携带由双35S启动子调控的玉米色素基因Lc和C1,可用作基因枪介导的共转化筛选标记,直观筛选含目标基因转基因材料;p WMB025载体携带由ubi启动子调控的、商业化转基因植物中广泛利用的EPSPS基因,可用于禾谷类作物农杆菌或基因枪介导的遗传转化,载体多克隆位点可通过酶切方式更换目标基因。酶切鉴定结合农杆菌或基因枪介导的小麦幼胚愈伤组织或叶片转化验证此3个载体表明,载体构建正确,其标记基因、可视化基因和报告基因均能正常表达。这3个载体的构建对于小麦等植物转化效率提升、安全型转基因作物获得和植物功能基因组学研究等具有重要意义。     

利用花青素可视化跟踪表达系统快速筛选表达Cry1Ab/c基因的转基因玉米

以草甘膦抗性基因Epsps为标记基因, 在原核Kan^r基因两侧引入Cre(环化重组酶)基因识别的Lox-P位点, 同时以编码花青素合成转录因子的Bi和Cl基因为可视化选择报告基因, 构建了Bt杀虫蛋白基因Cry1Ab/c的可视化跟踪表达载体pBAC9017。用PDS1000/He基因枪转化玉米(Zea mays)自交系501的幼胚和胚性愈伤组织, 获得147个草甘膦抗性的玉米再生植株。其中106棵植株获得了结实种子, 16棵植株的结实种子有紫红色花青素基因的表达。经PCR检测表明, 外源Cry1Ab/c基因已经整合到玉米的基因组中。转基因植株种子蛋白粗提物用BT-Cry1Ab/1Ac金标免疫检测试纸条和ELISA检测, 结果表明, Cry1Ab/c在部分转基因植株后代中表达。     

Assessment of simple marker-free genetic transformation techniques in alfalfa

Methods to avoid the presence of selectable marker genes (SMG) in transgenic plants are available but not implemented in many crop species. We assessed the efficiency of simple marker-free Agrobacterium-mediated transformation techniques in alfalfa: regeneration without selection, or marker-less, and co-transformation with two vectors, one containing the SMG and one containing a non-selected gene. To easily estimate the efficiency of marker-less transformation, the nptII and the GUS markers were used as non-selected genes. After Agrobacterium treatment, somatic embryos were regenerated without selection. The percentage of transgenic embryos was determined by a second cycle of regeneration using the embryos as starting material, in the presence of kanamycin, by PCR screening of T1 progenies, and by the GUS test. In two experiments, from 0 to 1.7% of the somatic embryos were transgenic. Co-transformation was performed with two vectors, one with the hemL SMG and one with the unselected nptII gene, each carried by a different culture of Agrobacterium. Only 15 putative co-transformed plants were regenerated from two experiments, with an average co-transformation percentage of 3.7. Southern blot hybridizations and/or T(1) progeny segregation were used to confirm transgene integration, and qPCR was also used to estimate the T-DNA copy number. In the T(1) progenies obtained by crossing with a non-transgenic pollinator, marker-free segregants were obtained. Both marker-free approaches showed very low efficiency.     

Transgenic peach plants (<Emphasis Type="Italic">Prunus persica</Emphasis> L.) produced by genetic transformation of embryo sections using the green fluorescent protein (GFP) as an <Emphasis Type="Italic">in vivo</Emphasis> marker

The main obstacle to genetic engineering of fruit tree species is the regeneration of transformed plantlets. Transformation events in peach (Prunus persica L.) have been reported using particle bombardment or Agrobacteriummediated transformation of immature embryos. However, the regeneration of plants from transgenic tissues is still difficult and the recovery of non-chimeric plants has not been reported to date. In this paper we describe an efficient, reliable transformation and regeneration system to produce transgenic peach plants using embryo sections of mature seeds as starting material. This represents an important advantage due to the availability of such material throughout the year. A. tumefaciens strain C58 (pMP90) containing the binary plasmid pBin19 was used as vector system for transformation. We used the Nospro-nptII-Noster cassette as a selectable marker and the CaMV35Spro-sgfp-CaMV35Ster cassette as a vital reporter gene coding for an improved version of the green fluorescent protein (sGFP). In vitro cultured embryo sections were Agrobacterium-cocultivated and, after selection, transgenic shoots were regenerated. Shoots that survived exhibited high-level of sGFP expression mainly visible in the young leaves of the apex. In vivo monitoring of GFP expression permitted an early, rapid and easy discrimination of both transgenic and escape buds. After elimination of escapes, transgenic shoots were rooted in vitro and the recovered plantlets were screened using PCR amplification. Southern analysis confirmed stable genomic integration of the sgfp transgene. The high levels of GFP expression were also maintained in the second generation of transgenic peach plants.     

Immature pollen-derived doubled haploid formation in barley cv. Golden Promise as a tool for transgene recombination

Barley transformation mediated by Agrobacterium tumefaciens is routinely performed in a number of laboratories. However, elimination of selectable marker genes and formation of plants homozygous for the transgene via conventional segregation is laborious and time-consuming. Here we suggest a concept that includes the production of primary transgenic plants via infection of immature embryos with A. tumefaciens followed by androgenetic generation of a segregating population of entirely homozygous plants. Selectable marker-free, truebreeding plants carrying a single-opy transgene integrant may thus be efficiently and rapidly obtained. However, amenability to Agrobacterium-mediated transformation as well as androgenetic potential is genotype-dependent. Efficient genetic transformation by infection of immature embryos is so far confined to the spring type cultivar ‘Golden Promise’ which, however, turned out to be recalcitrant in pollen embryogenesis. To facilitate androgenetic generation of homozygous segregants from primary transformants, we have established a method for embryogenic pollen culture in cv. Golden Promise that includes conventional cold-treatment and subsequent preculture of immature pollen under starvation conditions prior to transfer to complete nutrient medium. Further we show that conditioning of the pollen culture medium by co-culture of immature wheat pistils as well as addition of pistil-preconditioned medium considerably support androgenetic development. Employment of the established method using immature pollen of primary transgenic plants demonstrates that selectable marker-free, true-breeding transgenic progeny can be rapidly obtained pursuing the concept proposed. The protocol presented will be useful in functional genomics as well as in molecular breeding approaches.     

The elimination of a selectable marker gene in the doubled haploid progeny of co-transformed barley plants

Following the production of transgenic plants, the selectable marker gene(s) used in the process are redundant, and their retention may be undesirable. They can be removed by exploiting segregation among the progeny of co-transformants carrying both the selectable marker gene and the effector transgene. Here we show that the doubled haploid technology widely used in conventional barley breeding programmes represents a useful means of fixing a transgene, while simultaneously removing the unwanted selectable marker gene. Primary barley co-transformants involving hpt::gfp (the selectable marker) and gus (a model transgene of interest) were produced via Agrobacterium-mediated gene transfer to immature embryos using two respective T-DNAs. These plants were then subjected to embryogenic pollen culture to separate independently integrated transgenes in doubled haploid progeny. A comparison between 14 combinations, involving two Agrobacterium strains carrying various plasmids, revealed that the highest rate of independent co-transformation was achieved when a single Agrobacterium clone carried two binary vectors. Using this principle along with Agrobacterium strain LBA4404, selectable marker-free, gus homozygous lines were eventually obtained from 1.5 per 100 immature embryos inoculated. Compared to the segregation of uncoupled T-DNAs in conventionally produced progeny, the incorporation of haploid technology improves the time and resource efficiency of producing true-breeding, selectable marker-free transgenic barley.     

应用RNA干扰技术降低玉米支链淀粉含量

为了调控玉米淀粉的生物合成过程,克隆了玉米淀粉分支酶(starch branching enzymes,SBE)基因,构建高效的siRNA表达体系,通过花粉管通道法将其导入玉米自交系.PCR扩增和Southern杂交结果证明,目的基因已被整合到基因组中,且能够遗传.Northern杂交分析表明,该目的基因在转基因植株中能正常转录并导致内源SBE mRNA含量下降.对转基因植株淀粉分支酶活性和淀粉含量测定结果表明,分支酶活性明显地低于对照,相差最多的低85%;总淀粉含量与对照之间基本没有差异,但直链淀粉的含量提高了约50%.     

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。     

转基因植物中标记基因的剔除

在目前的植物转化系统中,要求在关注基因或目的基因转入细胞时,同时有标记基因存在.标记基因主要是抗生素或除草剂的抗性基因.借标记基因的表达可以将转化细胞从大量的未转化细胞中筛选出来,但标记基因的继续存在,特别是在转基因食品中,是人们广泛关注的问题.培育无标记基因的转基因植株已成为植物生物工程研究中的新课题.该文介绍了剔除标记基因的两种方法:分离剔除和重组剔除,并对近年来这两种方法在培育无标记基因的转基因植物中的应用和进展作了介绍.