利用FLP/frt重组系统产生无选择标记的转基因烟草植株

在植物转基因植株产生过程中,对转化细胞进行抗性筛选是通用程序,转化细胞的抗性一般是抗生素抗性或除草剂抗性,将赋予转化细胞抗性的选择标记基因删除是提高转基因植物生物安全性的重要措施。来自于啤酒酵母的FLP/frt位点特异性重组系统可有效删除同向定点重组位点frt之间的基因。通过多步骤重组,建立了可在植物中广泛应用的FLP/frt位点特异性重组系统。该系统包括含有frt位点的植物表达载体pCAMBIA1300-betA-frt-als-frt和含有由热诱导启动子hsp启动的FLP重组酶基因的植物表达载体pCAMBIA1300-hsp-FLP-hpt。利用二次转化的方式将二者先后转入烟草植株,热激处理后,热诱导型启动子hsp调控的重组酶FLP基因的表达催化位于选择标记基因als两侧同向frt位点间的重组反应,有效地删除了选择标记基因als。41%的经热激处理的二次转化植株发生了选择标记基因的删除,表明该系统在获得无选择标记基因的转基因植株中有很好的应用价值。     

Excision of selectable marker gene from transgenic tobacco using the GM-gene-deletor system regulated by a heat-inducible promoter

To excise a selectable marker gene from transgenic plants, a new binary expression vector based on the 'genetically modified (GM)-gene-deletor' system was constructed. In this vector, the gene coding for FLP site-specific recombinase under the control of a heat shock-inducible promoter HSP18.2 from Arabidopsis thaliana and isopentenyltransferase gene (ipt), as a selectable marker gene under the control of the cauliflower mosaic virus 35S (CaMV 35S) promoter, were flanked by two loxP/FRT fusion sequences as recombination sites in direct orientation. Histochemical staining for GUS activity showed that, upon induction by heat shock, all exogenous DNA, including the selectable marker gene ipt, beta-glucuronidase (gusA) gene and the FLP recombinase gene, between two loxP/FRT sites was eliminated efficiently from primary transgenic tobacco plants. Molecular analysis further confirmed that excision of the marker gene (ipt) was heritable and stable. Our approach provides a reliable strategy for auto-excising a selectable marker gene from calli, shoots or other tissues of transgenic plants after transformation and producing marker-free transgenic plants.     

Salicylic-Acid-Induced Self-excision of the Marker Gene <Emphasis Type="Italic">npt</Emphasis>II from Transgenic Tomato Using the Cre–<Emphasis Type="Italic">loxP</Emphasis> System

The presence of antibiotic-resistant genes in genetically engineered crops together with the target gene has generated a number of environmental and consumer concerns. In order to alleviate public concerns over the safety of food derived from transgenic crops, marker gene elimination is desirable. Marker-free transgenic tomato plants were obtained by using a salicylic-acid-regulated Cre–loxP-mediated site-specific DNA recombination system in which the selectable marker neomycin phosphotransferase nptII and cre genes were flanked by two directly oriented loxP sites. Upon induction by salicylic acid, the cre gene produced a recombinase that eliminated sequences encoding nptII and cre genes, sandwiched by two loxP sites from the tomato genome. Regenerant plants with the Cre–loxP system were obtained by selection on kanamycin media and polymerase chain reaction (PCR) screening. Transgenic plants were screened for excision by PCR using nptII, cre, and PR-1a promoter primers following treatment with salicylic acid. The footprint of the excision was determined by sequencing the T-DNA borders after a perfect recombination event. The excision efficiency was 38.7%. A new plant transformation vector, pBLNSC (Genbank accession number EU327497), was developed, containing six cloning sites and the self-excision system. This provided an effective approach to eliminate the selectable marker gene from transgenic tomato, thus expediting public acceptance of genetically modified tomato.     

Visual characterization of recombination at FRT-gusA loci in transgenic tobacco mediated by constitutive expression of the native FLP recombinase

FLP/FRT-mediated site-specific recombination was studied with a recombination-reporter gene system which allows visualization of -glucuronidase (GUS) expression after site-specific excisional activation of a silent gusA gene. This system was used for characterization of the functional activity of the Saccharomyces cerevisiae native FLP recombinase driven by the cauliflower mosaic virus (CaMV) 35s promoter [linked to the tobacco mosaic virus (TMV) omega translational leader] in mediating site-specific recombination of chromosomal FRT sites in tobacco FLP x FRT-reporter hybrids. Six hybrids were generated from crosses of lines containing either a stably integrated recombination-reporter or a FLP-expression construct. The activated gusA phenotype was specific to hybrid progenies and was not observed in either parental plants or their selfed progenies. Recombination efficiency in whole seedlings was estimated by the percent of radioactivity on a Southern blot which was incorporated into the recombined DNA product. Estimated efficiency mean values for the six crosses ranged from 5.2 to 52.0%. Histochemical analysis in hybrid plants visualized GUS activity with variable chimeric patterns and intensities. Recombination efficiency and GUS expression varied both among and within crosses, while higher recombination efficiency coincided with larger and more intense patterns of GUS activity. These data suggest that recombination is induced randomly during somatic developmental stages and that the pattern and intensity generated in a given plant are affected by factors imposing varibility not only between but also within crosses. Additionally, while recombination in a population of FLP/FRT hybrids may occur in all plants, recombination efficiency may still be low in any given plant. The activity of the native, as compared to a modified, FLP (Kilby et al. 1995) in the activation of transgenic traits in tobacco is discussed.     

FLP-mediated site-specific recombination in microinjected murine zygotes

The FLP recombinase of yeast catalyses site-specific recombination between repeated FLP recombinase target (FRT) elements in yeast and in heterologous system (Escherichia coli, Drosophila, mosquito and cultured mammalian cells). In this report, it is shown that transient FLP recombinase expression can recombine and activate an extrachromosomal silent reporter gene following coinjection into fertilized one-cell mouse eggs. Furthermore, it is demonstrated that introduction of a FLP-recombinase expression vector into transgenic one-cell fertilized mouse eggs induces a recombination event at a chromosomal FRT target locus. The resulting event occured at the one-cell stage and deleted a chromosomal tandem array of a FRT containinglacZ expression cassette down to one or two copies. These results demonstrate that the FLP recombinase can be utilized to manipulate the genome of transgenic animals and suggest that FLP recombinase-mediated plasmid-to-chromosome targeting is feasible in microinjected eggs.     

Inducible Excision of Selectable Marker Gene from Transgenic Plants by the Cre/<Emphasis Type="Italic">lox</Emphasis> Site-specific Recombination System

In a plant transformation process, it is necessary to use marker genes that allow the selection of regenerated transgenic plants. However, selectable marker genes are generally superfluous once an intact transgenic plant has been established. Furthermore, they may cause regulatory difficulties for approving transgenic crop release and commercialization. We constructed a binary expression vector with the Cre/lox system with a view to eliminating a marker gene from transgenic plants conveniently. In the vector, recombinase gene cre under the control of heat shock promoter and selectable marker gene nptII under the control of CaMV35S promoter were placed between two lox P sites in direct orientation, while the gene of interest was inserted outside of the lox P sites. By using this vector, both cre and nptII genes were eliminated from most of the regenerated plants of primary transformed tobacco through heat shock treatment, while the gene of interest was retained and stably inherited. This autoexcision strategy, mediated by the Cre/lox system and subjected to heat shock treatment to eliminate a selectable marker gene, is easy to adopt and provides a promising approach to generate marker-free transgenic plants.     

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.     

Elimination of marker genes and targeted integration via FLP/<Emphasis Type="BoldItalic">FRT</Emphasis> recombination system from yeast in hybrid aspen (<Emphasis Type="BoldItalic">Populus tremula</Emphasis> L. × <Emphasis Type="Italic">P. tremuloides</Emphasis> Michx.)

Marker gene elimination was investigated in hybrid aspen (Populus tremula L. × Populus tremuloides Michx.) using the FLP/FRT recombination system. The construct contained the FLP recombinase under control of a heat inducible promoter, the antibiotic resistance gene nptII driven by the CaMV 35S promoter, and a promoterless uidA gene. The construct was integrated into poplar via Agrobacterium-mediated transformation. The active FLP recombinase excised the nptII marker gene and combined the promoterless uidA gene with the CaMV 35S promoter to form an active uidA gene. For targeted transgene integration, two constructs were used. The first one carried FLP under control of the heat-inducible Gmhsp17.5-E promoter from soybean as well as an active nptII gene flanked by two FRT sites; the second contained the promoterless bar selection marker gene also flanked by two FRT sites. Following transformation and induction of FLP, the enzyme mediated a site-specific recombination at the FRT sites of both constructs. This recombination leads to an excision of the FLP and nptII gene from the first as well as an excision of the promoterless bar gene from the second construct. The promoterless bar gene reintegrated exactly at the former position of the FLP and nptII genes in the first construct to form an active bar gene. The FLP/FRT recombination system from yeast forms a promising basis for the production of antibiotic-free transgenic plants and a useful tool for directed integration of transgenes into plant genomes.     

Improved FLP Recombinase,FLPe, Efficiently Removes Marker Gene from Transgene Locus Developed by Cre–<Emphasis Type="Italic">lox</Emphasis> Mediated Site-Specific Gene Integration in Rice

Site-specific recombination systems, such as FLP–FRT and Cre–lox, carry out precise recombination reactions on their respective targets in plant cells. This has led to the development of two important applications in plant biotechnology: marker-gene deletion and site-specific gene integration. To draw benefits of both applications, it is necessary to implement them in a single transformation process. In order to develop this new process, the present study evaluated the efficiency of FLP–FRT system for excising marker gene from the transgene locus developed by Cre–lox mediated site-specific integration in rice. Two different FLP recombinases, the wild-type FLP (FLPwt) and its thermostable derivative, FLPe, were used for the excision of marker gene flanked by FLP recombination targets (FRT). While marker excision mediated by FLPwt was undetectable, use of FLPe resulted in efficient marker excision in a number of transgenic lines, with the relative efficiency reaching up to ~100%. Thus, thermo-stability of FLP recombinase in rice cells is critical for efficient site-specific recombination, and use of FLPe offers practical solutions to FLP–FRT-based biotechnology applications in plants.     

Removal of the Selectable Marker Gene from Transgenic Tobacco Plants by Expression of Cre Recombinase from a Tobacco Mosaic Virus Vector through Agroinfection

Selection markers are often indispensable during the process of plant transformation, but dispensable once transgenic plants have been established. The Cre/lox site-specific recombination system has been employed to eliminate selectable marker genes from transgenic plants. Here we describe the use of a movement function-improved Tobacco Mosaic Virus (TMV) vector, m30B, to express Cre recombinase for elimination of the selectable marker gene nptII from transgenic tobacco plants. The transgenic tobacco plants were produced by Agrobacterium-mediated transformation with a specially designed binary vector pGNG which contained in its T-DNA region a sequence complex of 35S promoter-lox-the gfp coding sequence-rbcS terminator-Nos promoter-nptII-Nos terminator-lox-the gus coding region-Nos terminator. The expression of the recombinant viral vector m30B:Cre in plant cells was achieved by placing the viral vector under the control of the 35S promoter and through agroinoculation. After co-cultivating the pGNG-leaf discs with agro35S-m30B:Cre followed by shoot regeneration without any selection, plants devoid of the lox-flanked sequences including nptII were obtained with an efficiency of about 34% as revealed by histochemical GUS assay of the regenerants. Three of 11 GUS expressing regenerants, derived from two independent transgenic lines containing single copy of the pGNG T-DNA, proved to be free of the lox-flanked sequences by Southern blot analysis. Excision of the lox-flanked sequences in the three plants could be attributed to transient expression of Cre from the viral vector at the early stage of co-cultivation, since the cre sequence could not be detected in the viral RNA molecules accumulated in the plants, nor in their genomic DNA. The parental marker-free genotype was inherited in their selfed progeny, and all of the progeny were virus-free, apparently because TMV is not seed-transmissible. Therefore, expression of Cre from a TMV-based vector could be used to eliminate selectable marker genes from transgenic tobacco plants without sexual crossing and segregation, and this strategy could be extended to other TMV-infected plant species and applicable to other compatible virus–host plant systems.     

Site-specific recombination in Zea mays

The elimination of marker genes after selection is recommended for the commercial use of genetically modified plants. We compared the applicability of the two site-specific recombination systems Cre/lox and Flp/FRT for marker gene elimination in maize plants. The selection marker gene pat surrounded by two identically directed lox or FRT sites was introduced into maize. Sexual crossing with plants harboring the corresponding constitutively expressed recombinase led to the precise and complete excision of the lox-flanked marker gene in the F₁ progeny, whereas Flp-mediated recombination of FRT sequences occurred rarely. Further examination of site-specific integration was done by biolistic bombardment of immature embryos harboring only one lox site with a lox.uidA sequence with results indicating directed integration.     

Combining a regeneration-promoting <Emphasis Type="Italic">ipt</Emphasis> gene and site-specific recombination allows a more efficient apricot transformation and the elimination of marker genes

The presence of marker genes conferring antibiotic resistance in transgenic plants represents a serious obstacle for their public acceptance and future commercialization. In addition, their elimination may allow gene stacking by the same selection strategy. In apricot, selection using the selectable marker gene nptII, that confers resistance to aminoglycoside antibiotics, is relatively effective. An attractive alternative is offered by the MAT system (multi-auto-transformation), which combines the ipt gene for positive selection with the recombinase system R/RS for removal of marker genes from transgenic cells after transformation. Transformation with an MAT vector has been attempted in the apricot cultivar ‘Helena’. Regeneration from infected leaves with Agrobacterium harboring a plasmid containing the ipt gene was significantly higher than that from non-transformed controls in a non-selective medium. In addition, transformation efficiencies were much higher than those previously reported using antibiotic selection, probably due to the integration of the regeneration-promoting ipt gene. However, the lack of an ipt expression-induced differential phenotype in apricot made difficult in detecting the marker genes excision and plants had to be evaluated at different times. PCR analysis showed that cassette excision start occurring after 6 months approximately and 1 year in culture was necessary for complete elimination of the cassette in all the transgenic lines. Excision was confirmed by Southern blot analysis. We report here for the first time in a temperate fruit tree that the MAT vector system improves regeneration and transformation efficiency and would allow complete elimination of marker genes from transgenic apricot plants by site-specific recombination.     

A Cre::FLP fusion protein recombines FRT or loxP sites in transgenic maize plants

SUMMARY: The coding sequences of Cre (site-specific recombinase from bacteriophage P1) and FLP (yeast 2-microm plasmid site-specific recombinase) were fused in frame to produce a novel, dual-function, site-specific recombinase gene. Transgenic maize plants containing the Cre::FLP fusion expression vector were crossed to transgenic plants containing either the loxP or FRT excision substrate. Complete and precise excisions of chromosomal fragments flanked by the respective target sites were observed in the F1 and F2 progeny plants. The episomal DNA recombination products were frequently lost. Non-recombined FRT substrates found in the F1 plants were recovered in the F2 generation after the Cre::FLP gene segregated out. They produced the recombination products in the F3 generation when crossed back to the FLP-expressing plants. These observations may indicate that the efficiency of site-specific recombination is affected by the plant developmental stage, with site-specific recombination being more prevalent in developing embryos. The Cre::FLP fusion protein was also tested for excisions catalysed by Cre. Excisions were identified in the F1 plants and verified in the F2 plants by polymerase chain reaction and Southern blotting. Both components of the fusion protein (FLP and Cre) were functional and acted with similar efficiency. The crossing strategy proved to be suitable for the genetic engineering of maize using the FLP or Cre site-specific recombination system.     

Flp recombinase transgenic mice of C57BL/6 strain for conditional gene targeting

We constructed an expression vector of Flp recombinase modified by adding a nuclear localization signal. Injection of the expression vector into fertilized eggs of the C57BL/6 strain yielded transgenic mouse lines expressing the Flp recombinase transgene in the testis. We crossed the transgenic mice to reporter mice carrying the neomycin phosphotransferase gene flanked by target sites of Flp recombinase. Examination of the deletion of the neomycin phosphotransferase gene in the progeny showed that Flp-mediated recombination took place efficiently in vivo in FLP66 transgenic mouse line. These results suggest that the Flp recombinase system is effective in mice and in combination with the Cre recombinase system extends the potentials of gene manipulation in mice. One of the useful applications of FLP66 transgenic mouse line is the removal of marker genes from mice manipulated for the conditional gene targeting with the Cre/loxP system in the pure C57BL/6 genetic background.     

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.     

Candida amazonensis FLP/FRT基因敲除系统的构建及初步验证

【目的】构建一个适用于Candida amazonensis抗性标记可重复使用的FLP/FRT基因敲除系统,并通过敲除C.amazonensis的丙酮酸脱羧酶基因(Pyruvate decarboxylase,PDC)对该系统进行初步验证。【方法】以gfpm(绿色荧光蛋白基因)为报告基因,通过添加相应诱导剂评估Spathaspora passalidarum来源启动子(SpXYLp、SpMAL6p、SpMAL1p、SpGAL1p)和Saccharomyces cerevisiae来源Sc GAL1p启动子在C.amazonensis中的诱导调控性能。选择严格诱导型启动子调控FLP重组酶的表达,并在FLP表达盒和潮霉素(Hygromycin B)抗性标记基因(hphm)两端添加同向重复的FRT位点,以PDC基因作为靶基因构建敲除盒PRFg HRP,转化宿主菌C.amazonensis CBS 12363,筛选得到阳性转化子后,通过添加诱导剂,表达FLP重组酶,实现FRT位点间片段切除。【结果】诱导调控实验表明启动子SpGAL1p(受半乳糖诱导)和SpMAL1p(受麦芽糖诱导)是适用于C.amazonensis的严格诱导型启动子。以SpGAL1p调控FLP基因表达,构建的敲除盒PRFg HRP成功转化宿主菌,获得阳性转化子C.amazonensis PDC01,通过添加半乳糖诱导,成功切除基因组中FLP表达盒和抗性标记盒,获得突变株C.amazonensis PDC02。【结论】首次建立了一个适用于C.amazonensis抗性标记可重复使用的FLP/FRT基因敲除系统,并利用该系统成功敲除了C.amazonensis内的PDC基因,为进一步利用代谢工程改造C.amazonensis酵母奠定了良好基础。     

Auto-excision of selectable marker genes from transgenic tobacco via a stress inducible FLP/FRT site-specific recombination system

Antibiotic resistance marker genes are powerful selection tools for use in plant transformation processes. However, once transformation is accomplished, the presence of these resistance genes is no longer necessary and can even be undesirable. We herein describe the successful excision of antibiotic resistance genes from transgenic plants via the use of an oxidative stress-inducible FLP gene. FLP encodes a recombinase that can eliminate FLP and hpt selection genes flanked by two FRT sites. During a transformation procedure in tobacco, transformants were obtained by selection on hygromycin media. Regenerants of the initial transformants were screened for selective marker excision in hydrogen peroxide supplemented media and both the FLP and hpt genes were found to have been eliminated. About 13–41% of regenerated shoots on hydrogen peroxide media were marker-free. This auto-excision system, mediated by the oxidative stress-inducible FLP/FRT system to eliminate a selectable marker gene can be very readily adopted and used to efficiently generate marker-free transgenic plants.