pBECKS2000: a novel plasmid series for the facile creation of complex binary vectors, which incorporates “clean-gene” facilities

A new plasmid series has been created for Agrobacterium-mediated plant transformation. The pBECKS2000 series of binary vectors exploits the Cre/loxP site-specific recombinase system to facilitate the construction of complex T-DNA vectors. The new plasmids enable the rapid generation of T-DNA vectors in which multiple genes are linked, without relying on the availability of purpose-built cassette systems or demanding complex, and therefore inefficient, ligation reactions. The vectors incorporate facilities for the removal of transformation markers from transgenic plants, while still permitting simple in vitro manipulations of the T-DNA vectors. A `shuttle' or intermediate plasmid approach has been employed. This permits independent ligation strategies to be used for two gene sets. The intermediate plasmid sequence is incorporated into the binary vector through a plasmid co-integration reaction which is mediated by the Cre/loxP site-specific recombinase system. This reaction is carried out within Agrobacterium cells. Recombinant clones, carrying the co-integrative binary plasmid form, are selected directly using the antibiotic resistance marker carried on the intermediate plasmid. This strategy facilitates production of co-integrative T-DNA binary vector forms which are appropriate for either (1) transfer to and integration within the plant genome of target and marker genes as a single T-DNA unit; (2) transfer and integration of target and marker genes as a single T-DNA unit but with a Cre/loxP facility for site-specific excision of marker genes from the plant genome; or (3) co-transfer of target and marker genes as two independent T-DNAs within a single-strain Agrobacterium system, providing the potential for segregational loss of marker genes.     

Design of a novel system for the construction of vectors for Agrobacterium-mediated plant transformation

Summary The loxP-Cre site-specific recombination system of phage P1 was used to develop a novel strategy to construct cointegrate vectors for Agrobacterium-mediated plant transformation. A pTi disarmed helper plasmid (pAL1166) was constructed by replacing the oncogenic T-DNA by a loxP sequence and a spectinomycin resistance marker in the octopine-type pTiB6 plasmid. The cre gene was cloned into an unstable incP plasmid. A third plasmid, which did not replicate in Agrobacterium and contained another loxP sequence together with a kanamycin resistance marker, was used to test the system. Electroporation of this third plasmid into an Agrobacterium strain harbouring both pAL1166 and the Cre-encoding plasmid resulted in kanamycin-resistant cells containing a cointegrate between pAL1166 and the incoming plasmid. Cointegration occurred by Cre-mediated recombination at the loxP sites, and the cointegrate was stabilized in the Agrobacterium cells by the loss of the Cre-encoding plasmid shortly after the recombination event had taken place.     

Excision of a selective marker in transgenic rice using a novel Cre/<Emphasis Type="Italic">loxP</Emphasis> system controlled by a floral specific promoter

Based on the Cre/loxP system, we have developed a novel marker-free system mediating a direct auto-excision of loxP-flanked marker genes from T₁ transgenic rice without any treatment or further offspring crossing. To achieve this, the floral-specific promoter OsMADS45 was isolated from rice and the expression patterns of OsMADS45 promoter was characterised by using the pOs45:GUS transgenic plants. Furthermore, the binary vector with Cre recombinase under the control of OsMADS45 promoter was constructed and introduced into rice by Agrobacterium-mediated transformation and transgenic rice plants were generated. Southern blot analysis showed that auto-excision of the selective markers occurred in some T₁ progeny of the transgenic plants, suggesting that a high auto-excision frequency can be achieved with our Cre/loxP system. This auto-excision strategy provides an efficient way of removing the selectable marker gene from transgenic rice. Xianquan Bai and Qiuyun Wang contributed equally to the work.     

A set of novel Ti plasmid-derived vectors for the production of transgenic plants

Summary We describe in this paper the construction and use of a set of novel Ti plasmid-derived vectors that can be used to produce transgenic plants. These vectors are based on one of two strategies: 1) double recombination into the wild-type Ti plasmid of genetic information flanked by two T-DNA fragments on a wide-host range plasmid; 2) the binary vector strategy. The vector based on the double recombination principle contains a kanamycin resistance gene for use as a plant selectable marker, a polylinker for the insertion of foreign genes, and a nopaline synthase gene. The vector was constructed such that a disarmed T-DNA results from the double recombination event. The binary vector combines several advantageous features including an origin of replication that is stable in Agrobacterium in the absence of selection, six unique sites for insertion of foreign genes, an intact nopaline synthase gene, and a kanamycin resistance marker for selection of transformed plant cells. All of these vectors have been used to produce tobacco plants transformed with a variety of foreign genes.     

The small,versatilepPZP family ofAgrobacterium binary vectors for plant transformation

The newpPZP Agrobacterium binary vectors are versatile, relatively small, stable and are fully sequenced. The vectors utilize the pTiT37 T-DNA border regions, the pBR322bom site for mobilization fromEscherichia coli toAgrobacterium, and the ColE1 and pVS1 plasmid origins for replication inE. coli and inAgrobacterium, respectively. Bacterial marker genes in the vectors confer resistance to chloramphenicol (pPZP100 series) or spectinomycin (pPZP200 series), allowing their use inAgrobacterium strains with different drug resistance markers. Plant marker genes in the binary vectors confer resistance to kanamycin or to gentamycin, and are adjacent to the left border (LB) of the transferred region. A lacZ -peptide, with the pUC18 multiple cloning site (MCS), lies between the plant marker gene and the right border (RB). Since the RB is transferred first, drug resistance is obtained only if the passenger gene is present in the transgenic plants.     

Cre/lox-mediated recombination in Arabidopsis: evidence for transmission of a translocation and a deletion event

Cre recombinase was used to mediate recombination between a chromosomally introduced loxP sequence in Arabidopsis thaliana (35S-lox-cre) and transferred DNA (T-DNA) originating from Agrobacterium tumefaciens (plox-npt), carrying a single loxP sequence. Constructs were designed for specific Cre-mediated recombination between the two lox sites, resulting in restoration of neomycin phosphotransferase (nptII) expression at the target locus. Kanamycin resistant (Km^r) recombinants were obtained with an efficiency of about 1% compared with random integration. Molecular analyses confirmed that these were indeed due to recombination between the lox sites of the target and introduced T-DNA. However, polymerase chain reaction analysis revealed that these reflected site-specific integration events only in a minority (4%). The other events were classified as translocations/inversions (71%) or deletions (25%), and were probably caused by site-specific recombination between a randomly integrated T-DNA and the original target locus. We studied some of these events in detail, including a Cre-mediated balanced translocation event, which was characterized by a combination of molecular, genetic and cytogenetic experiments (fluorescence in situ hybridization to spread pollen mother cells at meiotic prophase I). Our data clearly demonstrate that Agrobacterium-mediated transfer of a targeting T-DNA with a single lox site allows the isolation of multiple chromosomal rearrangements, including translocation and deletion events. Given that the complete sequence of the Arabidopsis genome will have been determined shortly this method has significant potential for applications in functional genomics. Received: 29 December 1999; in revised form: 21 February 2000 / Accepted: 2 March 2000     

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.     

Non-oncogenic plant vectors for use in the agrobacterium binary system

Summary Agrobacterium strains harbouring the T-region and the virulence-region of the Ti plasmid on separate replicons still display efficient T-DNA transfer to plants. Based on this binary vector strategy we have constructed T-region derived gene vectors for the introduction of foreign DNA into plants. The vectors constructed can replicate in E. coli, thus the genetic manipulations with them can be performed with E. coli as a host. They can be transferred to Agrobacterium as a cointegrate with the wide host range plasmid R772. Their T-regions are transferred to plant cells from Agrobacterium strains conferring virulence functions.The plasmid pRAL 3940 reported here is 11.5 kb large, contains a marker to identify transformed plant cells and unique restriction sites for direct cloning of passenger DNA, flanked by the left- and right-hand border fragments of the T-region (including the 25 bp border repeats). The plasmid is free of onc-genes. Therefore, is does not confer tumorigenic traits on the transformed plant cells and mature, fertile plants can thus be regenerated from them.     

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.     

Selective Disruption of Genes Transiently Induced in Differentiating Mouse Embryonic Stem Cells by Using Gene Trap Mutagenesis and Site-Specific Recombination

A strategy employing gene trap mutagenesis and site-specific recombination (Cre/loxP) has been used to identify genes that are transiently expressed during early mouse development. Embryonic stem cells expressing a reporter plasmid that codes for neomycin phosphotransferase and Escherichia coli LacZ were infected with a retroviral gene trap vector (U3Cre) carrying coding sequences for Cre recombinase (Cre) in the U3 region. Activation of Cre expression from integrations into active genes resulted in a permanent switching between the two selectable marker genes and consequently the expression of β-galactosidase (β-Gal). As a result, clones in which U3Cre had disrupted genes that were only transiently expressed could be selected. Moreover, U3Cre-activating cells acquired a cell autonomous marker that could be traced to cells and tissues of the developing embryo. Thus, when two of the clones with inducible U3Cre integrations were passaged in the germ line, they generated spatial patterns of β-Gal expression.     

Cre recombinase‐mediated site‐specific modification of a cellular genome using an integrase‐defective retroviral vector

Retroviral integrase is an enzyme responsible for the integration of retroviruses. A single mutation in the integrase core domain can severely compromise its integration ability, leading to the accumulation of circular retroviral cDNA in the nuclei of infected cells. We therefore attempted to use those cDNA as substrates for Cre recombinase to perform a recombinase‐mediated cassette exchange (RMCE), thereby targeting retroviral vectors to a predetermined site. An expression unit containing a promoter, an ATG codon and marker genes (hygromycin resistance gene and red fluorescent protein gene) flanked by wild‐type and mutant loxP sites was first introduced into cellular chromosome to build founder cell lines. We then constructed another plasmid for the production of integrase‐defective retroviral vectors (IDRV), which contains an ATG‐deficient neomycin resistance gene and green fluorescent protein gene, flanked by a compatible pair of loxPs. After providing founder cells with Cre and infecting with IDRV later, effective RMCE occurred, resulting in the appearance of G418‐resistant colonies and a change in the color of fluorescence from red to green. Southern blot and PCR analyses on selected clones further confirmed site‐specific recombination. The successful substitution of the original viral integration machinery with a non‐viral mechanism could expand the application of retroviral vectors. Biotechnol. Bioeng. 2010;107:717–729. © 2010 Wiley Periodicals, Inc.     

pBECKS

A series of binary T-DNA vectors (pBECKS) has been created for use in theAgrobacterium-mediated genetic transformation of plants. The pBECKS series has corrected the undesirable features of the popular pBIN19 vector; the deleterious mutation within the coding sequence ofnptII has been amended and the cloning sites are now adjacent to the right border repeat in order to reduce the possibility of producing truncated sequences of novel genes within transformants. One set of vectors incorporates various combiantions of the marker genesgusA,C1/Lc,nptII,hph, andbar, for pursuit of early and stable transformation events. A set of constructs which contain deleted T-DNA borders in various combinations and display predictably altered efficacies for gene transfer has also been created. A modular set of vectors has been designed to facilitate the insertion and transfer of novel gene sequences by providing anptII-linked plant expression cassette orlacZ-multiple cloning site. A range of antibiotic resistance genes has been incorporated into the non-T-DNA part of the vectors in order to facilitate their selection across the range ofAgrobacterium virulence strains.     

Simultaneous on/off regulation of transgenes located on a mammalian chromosome with Cre-expressing adenovirus and a mutant loxP

The site-specific recombinase Cre has often been used for on/off regulation of expression of transgenes introduced into the mammalian chromosome. However, this method is only applicable to the regulation of a single gene and cannot be used to simultaneously regulate two genes, because site-specific recombination occurs from the target loxP sequence of one regulating unit to the loxP sequence of any other unit and would eventually disrupt the structure of both regulating units. We previously reported a mutant loxP sequence with a two base substitution called loxP V (previously called loxP 2272), with which wild-type loxP cannot recombine but with which the identical mutant loxP recombines efficiently. In the present study we isolated cell lines bearing two regulating units on a chromosome containing a pair of wild-type loxP sequences or mutant loxP V sequences. After infection with Cre-expressing recombinant adenovirus AxCANCre, expression of a gene in each regulating unit was simultaneously turned on and off. Southern analyses showed that both regulating units were processed simultaneously and independently, even after infection with a limited amount of AxCANCre. The results showed that simultaneous regulation of gene expression on a mammalian chromosome mediated by Cre can be achieved by using mutant loxP V and wild-type loxP. This method may be a useful approach for conditional transgenic/knockout animals and investigation of gene function involving two genes simultaneously. Another possible application is for preparation of a new packaging cell line of viral vectors through simultaneous production of toxic viral genes.     

An accumulative site‐specific gene integration system using cre recombinase‐mediated cassette exchange

The Cre‐loxP system is frequently used for site‐specific recombination in animal cells. The equilibrium and specificity of the recombination reaction can be controlled using mutated loxPs. In the present study, we designed an accumulative site‐specific gene integration system using Cre recombinase and mutated loxPs in which the Cre‐mediated cassette exchange reaction is infinitely repeatable for target gene integration into loxP target sites. To evaluate the feasibility and usefulness of this system, a series of integration reactions were repeated and confirmed in vitro using Cre recombinase protein and plasmids. Accumulative gene integration was also performed on the genome of Chinese hamster ovary (CHO) cells. The results indicated that the system was applicable for repeated gene integration of multiple genes to the target sites on both plasmids and CHO cell genomes. This gene integration system provides a novel strategy for gene amplification and for biological analyses of gene function through the genetic modification of cells and organisms. Biotechnol. Bioeng. 2010;105: 1106–1114. © 2009 Wiley Periodicals, Inc.     

Use of the Cre-loxP recombination system as an estimate for Agrobacterium-mediated co-transformation of tobacco leaves

Agrobacterium tumefaciens-mediated transformation of tobacco leaves (Nicotiana tabacum) is used to study gene expression in a heterologous genetic background. Here, the Cre-loxP recombination system was used to detect T-DNA transfer by two A. tumefaciens cells harboring different binary vectors. Cre, under the control of the CaMV 35S promoter, was cloned into one vector, and a loxP cassette into another vector. A mixture of A. tumefaciens, in which each cell contained either a Cre- or loxP-vector, was co-infiltrated into tobacco leaves. After two days, excision of loxP-flanked DNA was detected by PCR and used as an estimate for co-transformation events. Strongest excision (> 50%) was observed when the loxP cassette was cloned into vector pPZP112 and Cre into pISV2678. This fast and easy technique can be used to assess the co-transformation efficiency of tobacco cells in future studies.     

A new site-specific recombinase-mediated system for targeted multiple genomic deletions employing chimeric loxP and mrpS sites

A newly designed site-specific recombination system is presented which allows multiple targeted markerless deletions. The most frequently used tool for removing selection markers or to introduce genes by recombination-mediated cassette exchange is the Cre/loxP system. Many mutant loxP sites have been created for this purpose. However, this study presents a chimeric mutant loxP site denoted mroxP-site. The mroxP site consists of one Cre (loxP/2) and one MrpA (mrpS/2) binding site separated by a palindromic 6-bp spacer sequence. Two mroxP-sites can be recombined by Cre recombinase in head-to-tail as well as in head-to-head orientation. In the head-to-head orientation and the loxP half-sites inside, Cre removes the loxP half-sites during site-specific recombination, creating a new site, mrmrP. The new site is essentially a mrpS site with a palindromic spacer and cannot be used by Cre for recombination anymore. It does, however, present a substrate for the recombinase MrpA. This new system has been successfully applied introducing multiple targeted gene deletions into the Escherichia coli genome. Similar to Cre/loxP and FLP/FRT, this system may be adapted for genetic engineering of other pro- and eukaryotes.     

pORE: a modular binary vector series suited for both monocot and dicot plant transformation

We present a series of 14 binary vectors suitable for Agrobacterium-mediated transformation of dicotyledonous plants and adaptable for biolistic transformation of monocotyledonous plants. The vector size has been minimized by eliminating all non-essential elements from the vector backbone and T-DNA regions while maintaining the ability to replicate independently. The smallest of the vector series is 6.3 kb and possesses an extensive multiple cloning site with 21 unique restriction endonuclease sites that are compatible with common cloning, protein expression, yeast two-hybrid and other binary vectors. The T-DNA region was engineered using a synthetic designer oligonucleotide resulting in an entirely modular system whereby any vector element can be independently exchanged. The high copy number ColE1 origin of replication has been included to enhance plasmid yield in Escherichia coli. FRT recombination sites flank the selectable marker cassette regions and allow for in planta excision by FLP recombinase. The pORE series consists of three basic types; an ‘open’ set for general plant transformation, a ‘reporter’ set for promoter analysis and an ‘expression’ set for constitutive expression of transgenes. The sets comprise various combinations of promoters (P _HPL, P _ENTCUP2 and P _TAPADH), selectable markers (nptII and pat) and reporter genes (gusA and smgfp).     

Efficient removal of loxP-flanked DNA sequences in a gene-targeted locus by transient expression of Cre recombinase in fertilized eggs

The bacteriophage P1 Cre/loxP site-specific recombination system is a useful tool for engineering chromosomal changes in animal cells. Transient expression of the Cre recombinase gene directly introduced into fertilized eggs by pronuclear injection has been reported to provide an efficient method of transgene modulation in fertilized eggs. In the present study, we examined the efficacy of this method to remove loxP-flanked DNA sequences in a gene-targeted locus in fertilized eggs. We replaced a part of the T-cell receptor γ (TCR Vγ) locus with homologous sequences containing a loxP-flanked neogene in mouse embryonic stem (ES) cells by gene-targeting technique. The resulting ES cell clones containing the mutant allele (Vγ^LNL) were used to generate chimeric mice by blastocyst injection. Eight male chimeras were bred with superovulated wild-type female mice. One hundred and seventy-six fertilized eggs were collected, and subjected to pronuclear injection of the Cre expression plasmid, pCAGGS-Cre, of a covalently closed circular form. Three out of 11 pups inherited the targeted Vγ locus. The inherited targeted allele of these 3 mice was shown to have undergone Cre-mediated recombination, resulting in a deletion of the loxP-flanked sequences (Vγ^Δ) as shown by Southern blot analysis of DNA from tail biopsies. All 3 founder mutant mice were capable of transmitting the Vγ^Δ locus to their offspring. The other 8 pups carried only wild-type alleles. There were no pups carrying the unrecombined Vγ^LNL locus. Thus, the frequency of Cre-mediated recombination was 100% (3/3) with this method. In contrast, when closed circular pCAGGS-Cre plasmid was introduced into ES cells by electroporation, the recombination frequency of the Vγ^LNL locus was 9.6%. These results indicated that our system based on transient expression of the Cre recombinase gene directly introduced into fertilized eggs by pronuclear injection provides a fast and efficient method for generating mutant mice with desired deletions or translocations in target genes. Mol Reprod Dev 46:109–113, 1997. © 1997 Wiley-Liss, Inc.     

Polymerase chain reaction analysis of transgenic plants contaminated byAgrobacterium

Agrobacterium-mediated genetic transformation is a method of choice for the development of transgenic plants. The presence of latentAgrobacterium that multiplies in the plant tissue in spite of antibiotic application confounds the results obtained by polymerase chain reaction (PCR) analysis of putative transgenic plants. The presence ofAgrobacterium can be confirmed by amplification of eitherAgrobacterium chromosomal genes or genes present out of transfer DNA (T-DNA) in the binary vector. However, the transgenic nature ofAgrobacterium-contaminated transgenic plants cannot be confirmed by PCR. Here we report a simple protocol for PCR analysis ofAgrobacterium-contaminated transgenic plants. This protocol is based on denaturation and renaturation of DNA. The contaminating plasmid vector becomes double-stranded after renaturation and is cut by a restriction enzyme having site(s) within the PCR amplicon. As a result, amplification by PCR is not possible. The genomic DNA with a few copies of the transgene remains single-stranded and unaffected by the restriction enzyme, leading to amplification by PCR. This protocol has been successfully tested with 4 different binary vectors and 3Agrobacterium tumefaciens strains: EHA105, LBA4404, and GV3101.     

The Agrobacterium rhizogenes pRi TL-DNA segment as a gene vector system for transformation of plants

Summary A plant gene transfer system was developed from the Agrobacterium rhizogenes pRi15834 TL-DNA region. Intermediate integration vectors constructed from ColE1-derived plasmids served as cloning vectors in Escherichia coli and formed cointegrates into the TL-DNA after transfer to A. rhizogenes. An A. rhizogenes strain with pBR322 plasmid sequences replacing part of the TL-DNA was also constructed. Plasmids unable to replicate in Agrobacterium can integrate into this TL-DNA by homologous recombination through pBR322 sequences. No loss of pathogenicity was observed with the strains formed after integration of intermediate vectors or strains carrying pBR322 in the TL-DNA segment. Up to 15 kb of DNA have been transferred to plant cells with these systems. The T-DNA from a binary vector was cotransformed into hairy roots which developed after transfer of the wild-type pRi T-DNA. Tested on Lotus corniculatus the TL-derived vector system transformed 90% of the developed roots and the T-DNA from the binary vector was cotransformed into 60% of the roots. Minimum copy numbers of one to five were found. Both constitutive and organ-specific plant genes were faithfully expressed after transfer to the legume L. corniculatus.