Yeast-based recombineering of DNA fragments into plant transformation vectors by one-step transformation

T-DNA binary vectors are often used in plant transformation experiments. Because they are usually very large and have few restriction sites suitable for DNA ligation reactions, cloning DNA fragments into these vectors is difficult. We provide herein an alternative to cloning DNA fragments into very large vectors. Our yeast-based recombineering method enables DNA fragments to be cloned into certain types of T-DNA binary vectors by one-step transformation without the requirement of specific recombination sites or precisely positioned restriction ends, thus making the cloning process more flexible. Moreover, this method is inexpensive and is applicable to multifragment cloning.     

A gateway cloning vector set for high-throughput functional analysis of genes in planta

The current challenge, now that two plant genomes have been sequenced, is to assign a function to the increasing number of predicted genes. In Arabidopsis, approximately 55% of genes can be assigned a putative function, however, less than 8% of these have been assigned a function by direct experimental evidence. To identify these functions, many genes will have to undergo comprehensive analyses, which will include the production of chimeric transgenes for constitutive or inducible ectopic expression, for antisense or dominant negative expression, for subcellular localization studies, for promoter analysis, and for gene complementation studies. The production of such transgenes is often hampered by laborious conventional cloning technology that relies on restriction digestion and ligation. With the aim of providing tools for high throughput gene analysis, we have produced a Gateway-compatible Agrobacterium sp. binary vector system that facilitates fast and reliable DNA cloning. This collection of vectors is freely available, for noncommercial purposes, and can be used for the ectopic expression of genes either constitutively or inducibly. The vectors can be used for the expression of protein fusions to the Aequorea victoria green fluorescent protein and to the beta-glucuronidase protein so that the subcellular localization of a protein can be identified. They can also be used to generate promoter-reporter constructs and to facilitate efficient cloning of genomic DNA fragments for complementation experiments. All vectors were derived from pCambia T-DNA cloning vectors, with the exception of a chemically inducible vector, for Agrobacterium sp.-mediated transformation of a wide range of plant species.     

Efficient octopine Ti plasmid-derived vectors for Agrobacterium-mediated gene transfer to plants.

A two-component cloning system to transfer foreign DNA into plants was derived from the octopine Ti plasmid pTiB6S3. pGV2260 is a non-oncogenic Ti plasmid from which the T-region is deleted and substituted by pBR322. pGV831 is a streptomycin-resistant pBR325 derivative that contains a kanamycin resistance marker gene for plant cells and a site for cloning foreign genes between the 25-bp border sequences of the octopine T-region. Conjugative transfer of pGV831 derivatives to Agrobacterium and cointegration by homologous recombination between the pBR322 sequences present on pGV831 and pGV2260, can be obtained in a single step. Strains carrying the resulting cointegrated plasmids transfer and integrate T-DNA into the genome of tobacco protoplasts, and transformed tobacco calli are readily selected as resistant to kanamycin. Intact plants containing the entire DNA region between the T-DNA borders have been regenerated from such clones. In view of these properties we present pGV831 and its derivatives as vectors for efficient integration of foreign genes into plants.     

A mini binary vector series for plant transformation

A streamlined mini binary vector was constructed that is less than 1/2 the size of the pBIN19 backbone (3.5 kb). This was accomplished by eliminating over 5 kb of non-T-DNA sequences from the pBIN19 vector. The vector still retains all the essential elements required for a binary vector. These include a RK2 replication origin, the nptIII gene conferring kanamycin resistance in bacteria, both the right and left T-DNA borders, and a multiple cloning site (MCS) in between the T-DNA borders to facilitate cloning. Due to the reduced size, more unique restriction sites are available in the MCS, thus allowing more versatile cloning. Since the traF region was not included, it is not possible to mobilize this binary vector into Agrobacterium by triparental mating. This problem can be easily resolved by direct transformation. The mini binary vector has been demonstrated to successfully transform Arabidopsis plants. Based on this mini binary vector, a series of binary vectors were constructed for plant transformation.     

The interaction of Agrobacterium Ti-plasmid DNA and plant cells

The tumour-inducing plasmids of Agrobacterium tumefaciens (Ti-plasmids) reveal several interesting properties. They are catabolic plasmids, which, instead of rendering Agrobacterium strains capable of catabolizing compounds found in Nature, force a plant to synthesize these catabolites (denoted 'opines'). This situation is obtained by insertion of a segment of the Ti-plasmid (the T-DNA) into the plant nucleus, where T-DNA genes become expressed and intervene in the biosynthesis of these opines. Cells containing the T-DNA behave as neoplasms (crown gall cells). Southern blotting shows that the insertion process responsible for T-DNA transfer probably recognizes special sequences on the T-DNA since the length of the T-DNA segment observed in different, independently isolated tumour lines was found to be similar. For the nopaline Ti-plasmids both left-hand and right-hand borders were found to be constant. For the octopine plasmid the left border was constant and at least two classes of right-hand borders were found. Upon redifferentiation of the transformed plant cells, the T-DNA was found to be conserved in all somatic cells examined. However, small deletions at the border fragments of the T-DNA have been observed. The exact arrangement and copy number of the T-DNA in a nucleus is still under study, but genomic cloning has already revealed that an interspersed tandem arrangement is dominant in nopaline tumours. Clones containing both the right border of one T-DNA and the left border of the neighbouring tandem T-DNA were isolated. In order to identify the different T-plasmid encoded functions an extensive use was made of transposon insertion mutagenesis. When an antibiotic resistance transposon was inserted into the non-essential regions of the T-DNA, a linked transfer to the plant DNA of the transposon together with the T-DNA was observed. This indicates that Ti-plasmids are possible vectors for genetic engineering in plants. A strategy is described for insertion of any cloned DNA segment into the T-DNA.     

A plant transformation vector with a minimal T-DNA

Plant transformation, viaAgrobacterium tumefaciens, is usually performed with binary vectors. Most of the available binary vectors contain within the T-DNA (which is transferred to the plant genome) components not required for the intended modification. These additional sequences may cause potential risks during field testing of the transgenic plants or even more in the case of commercialization. The aim of this study was to produce a plant transformation vector which only contains a selectable and screenable marker gene and a multiple cloning site for insertion of promoter::foreign gene::terminator cassettes from other plasmids.     

Extension of the host range of Escherichia coli vectors by incorporation of RSF1010 replication and mobilization functions.

The broad-host-range vectors pSUP104, pSUP106, pSUP204, pSUP304, and pSUP404 are based on conventional Escherichia coli vectors (such as pBR325 and pACYC184) which have been modified to include the mobilization and broad-host-range replication functions of the IncQ plasmid RSF1010. These vector plasmids now can be maintained in a wide range of bacterial genera including Rhizobium, Agrobacterium, and Pseudomonas. They are efficiently mobilized by RP4 and thus are of particular interest for bacteria refractory to transformation. They offer the selection markers and cloning sites characteristic of the basic E. coli vectors. Therefore, they can be applied and adapted to a variety of cloning strategies. However, the cloning of very large fragments (e.g., in cosmid hybrids of pSUP106) was found to affect the stability of the recombinant molecules in a Rec+ background. This instability was not observed with smaller inserts of about 5 kilobases.     

Agroinfection

Agroinfection, the delivery of viral or viroidal sequences to plants by Agrobacterium, can be used to approach important basic questions in plant molecular biology. The combined use of three biological entities allows the analysis of plant-Agrobacterium interactions using the virus as a marker for T-DNA transfer, or the investigation of viral biology using Agrobacterium as a delivery vehicle for the virus. Plants transgenic for viral constructs offer possibilities for studying recombination, plant protection, and development of high copy number plant vectors. Relevant examples of these approaches are discussed.     

Agrobacterium proteins VirD2 and VirE2 mediate precise integration of synthetic T-DNA complexes in mammalian cells

Agrobacterium tumefaciens-mediated plant transformation, a unique example of interkingdom gene transfer, has been widely adopted for the generation of transgenic plants. In vitro synthesized transferred DNA (T-DNA) complexes comprising single-stranded DNA and Agrobacterium virulence proteins VirD2 and VirE2, essential for plant transformation, were used to stably transfect HeLa cells. Both proteins positively influenced efficiency and precision of transgene integration by increasing overall transformation rates and by promoting full-length single-copy integration events. These findings demonstrate that the virulence proteins are sufficient for the integration of a T-DNA into a eukaryotic genome in the absence of other bacterial or plant factors. Synthetic T-DNA complexes are therefore unique protein:DNA delivery vectors with potential applications in the field of mammalian transgenesis.     

Segregation of genes transferred to one plant cell from two separate Agrobacterium strains

Agrobacterium tumefaciens and Agrobacterium rhizogenes are soil bacteria which transfer DNA (T-DNA) to plant cells. Two Agrobacterium strains, each with a different T-DNA, can infect plants and give rise to transformed tissue which has markers from both T-DNAs. Although marker genes from both T-DNAs are in the tissue, definitive proof that the tissue is a cellular clone and that both T-DNAs are in a single cell is necessary to demonstrate cotransformation. We have transferred two distinguishable T-DNAs, carried on binary vectors in separate Agrobacterium rhizogenes strains, into tomato cells and have recovered hairy roots which received both T-DNAs. Continued expression of marker genes from each T-DNA in hairy roots propagated from individual root tips indicated that both T-DNAs were present in a single meristem. Also, we have transferred the two different T-DNAs, carried on identical binary vector plasmids in separate Agrobacterium tumefaciens strains, into tobacco cells and recovered plants which received both T-DNAs. Transformed plants with marker genes from each T-DNA were outcrossed to wild-type tobacco plants. Distribution of the markers in the F1 generation from three cotransformed plants of independent origin showed that both T-DNAs in the plants must have been present in the same cell and that the T-DNAs were genetically unlinked. Cotransformation of plant cells with T-DNAs from two bacterial strains and subsequent segregation of the transferred genes should be useful for altering the genetic content of higher plants.     

Vectors carrying two separate T-DNAs for co-transformation of higher plants mediated by Agrobacterium tumefaciens and segregation of transformants free from selection markers

Novel ‘super-binary’ vectors that carried two separate T-DNAs were constructed. One T-DNA contained a drug-resistance, selection-marker gene and the other contained a gene for β-glucuronidase (GUS). A large number of tobacco (Nicotiana tabacum L.) and rice (Oryza sativa L.) transformants were produced by Agrobacterium tume-faciens LBA4404 that carried the vectors. Frequency of co-transformation with the two T-DNAs was greater than 47%. GUS-positive, drug-sensitive progeny were obtained from more than half of the co-transformants. Molecular analyses by Southern hybridization and polymerase chain reactions confirmed integration and segregation of the T-DNAs. Thus, the non-selectable T-DNA that was genetically separable from the selection marker was integrated into more than a quarter of the initial, drug-resistant transformants. Since various DNA fragments may be inserted into the non-selectable T-DNA by a simple procedure, these vectors will likely be very useful for the production of marker-free transformants of diverse plant species. Delivery of two T-DNAs to plants from mixtures of A. tumefaciens was also tested, but frequency of co-transformation was relatively low.     

Modular cloning in plant cells

New plant genes are being discovered at a rapid pace. Yet, in most cases, their precise function remains elusive. The recent advent of recombinational cloning techniques has significantly improved our ability to investigate gene functions systematically. For example, proteins fused with diverse fluorescent tags can be expressed at will using versatile cloning cassettes. In addition, novel binary T-DNA vectors are now available to assemble multiple DNA fragments simultaneously, which greatly facilitate plant cell and protein engineering.     

提高水稻插入突变体库利用效率的尝试

T-DNA标签法是一种以农杆菌介导的遗传转化为基础来创造插入突变体库, 从而高通量地分离和克隆植物功能基因的方法。但由于种种原因, 水稻插入突变体库的利用效率较低。为了提高水稻插入突变体库的利用效率, 结合水稻一个双拷贝T-DNA插入突变体的发现和鉴定研究, 通过特异PCR检测、侧翼序列与目标性状的共分离分析, 在1个双插入位点均为杂合的植株的后代株系中分拆了2个插入事件, 分离出目标性状存在遗传分离且只带有1个插入事件的后代株系, 为后续的共分离检测和基因克隆研究打下了重要的基础。由此产生了对插入突变体库中的非串联多拷贝插入标签系进行研究的一些思路和方法, 提出来与同行商榷。     

The pCLEAN dual binary vector system for Agrobacterium-mediated plant transformation

The development of novel transformation vectors is essential to the improvement of plant transformation technologies. Here, we report the construction and testing of a new multifunctional dual binary vector system, pCLEAN, for Agrobacterium-mediated plant transformation. The pCLEAN vectors are based on the widely used pGreen/pSoup system and the pCLEAN-G/pCLEAN-S plasmids are fully compatible with the existing pGreen/pSoup vectors. A single Agrobacterium can harbor (1) pCLEAN-G and pSoup, (2) pGreen and pCLEAN-S, or (3) pCLEAN-G and pCLEAN-S vector combination. pCLEAN vectors have been designed to enable the delivery of multiple transgenes from distinct T-DNAs and/or vector backbone sequences while minimizing the insertion of superfluous DNA sequences into the plant nuclear genome as well as facilitating the production of marker-free plants. pCLEAN vectors contain a minimal T-DNA (102 nucleotides) consisting of direct border repeats surrounding a 52-nucleotide-long multiple cloning site, an optimized left-border sequence, a double left-border sequence, restriction sites outside the borders, and two independent T-DNAs. In addition, selectable and/or reporter genes have been inserted into the vector backbone sequence to allow either the counter-screening of backbone transfer or its exploitation for the production of marker-free plants. The efficiency of the different pCLEAN vectors has been assessed using transient and stable transformation assays in Nicotiana benthamiana and/or Oryza sativa.     

Cre/lox-mediated site-specific integration of Agrobacterium T-DNA in Arabidopsis thaliana by transient expression of cre

The Cre/lox system was used to obtain targeted integration of an Agrobacterium T-DNA at a lox site in the genome of Arabidopsis thaliana. Site-specific recombinants, and not random events, were preferentially selected by activation of a silent lox-neomycin phosphotransferase (nptII) target gene. To analyse the effectiveness of Agrobacterium-mediated transfer we used T-DNA vectors harbouring a single lox sequence (this vector had to circularize at the T-DNA left- and right-border sequences prior to site-specific integration) or two lox sequences (this vector allowed circularization at the lox sequences within the T-DNA either prior to or after random integration, followed by targeting of the circularized vector), respectively. Furthermore, to control the reversibility of the integration reaction, Cre recombinase was provided transiently by using a cotransformation approach. One precise stable integrant was found amongst the recombinant calli obtained after transformation with a double-lox T-DNA vector. The results indicate that Agrobacterium-mediated transformation can be used as a tool to obtain site-specific integration.     

利用双T-DNA载体系统培育无选择标记转基因烟草

建立了一种利用双T-DNA载体培育无选择标记转基因植物的方法.通过体外重组构建了双T-DNA双元载体pDLBRBbarm.载体中,选择标记nptⅡ基因和另一代表外源基因的bar基因分别位于2个独立的T-DNA.利用农杆菌介导转化烟草(Nicotiana tabacum L.),在获得的转化植株中,同时整合有nptⅡ基因和bar基因的频率为59.2%.对4个同时整合有nptⅡ和bar基因植株自交获得的T1代株系进行检测分析,发现在3个T1代株系2个T-DNA可以发生分离,其中约19.5%的转基因T1代植株中只存在bar基因而不带选择标记nptⅡ.这一结果说明双T-DNA载体系统能有效地用于培育无选择标记的转基因植物.研究还利用位于2个不同载体上的nptⅡ基因与 bar基因通过农杆菌介导共转化烟草,获得共转化植株的频率为20.0%～47.4%,低于使用双T-DNA转化的共转化频率.