Lan-Ying Lee

T-DNA Binary Vectors and Systems

For more than two decades, scientists have used Agrobacterium-mediated genetic transformation to generate transgenic plants. Initial technologies to introduce genes of interest (goi) into Agrobacterium involved complex microbial genetic methodologies that inserted these goi into the transfer DNA (T-DNA) region of large tumor-inducing plasmids (Ti-plasmids). However, scientists eventually learned that T-DNA transfer could still be effected if the T-DNA region and the virulence (vir) genes required for T-DNA processing and transfer were split into two replicons. This binary system permitted facile manipulation of Agrobacterium and opened up the field of plant genetic engineering to numerous laboratories. In this review, we recount the history of development of T-DNA binary vector systems, and we describe important components of these systems. Some of these considerations were previously described in a review by Hellens et al. (2000b).

Identification of Arabidopsis rat mutants

Limited knowledge currently exists regarding the roles of plant genes and proteins in the Agrobacterium tumefaciens-mediated transformation process. To understand the host contribution to transformation, we carried out root-based transformation assays to identify Arabidopsis mutants that are resistant to Agrobacterium transformation (rat mutants). To date, we have identified 126 rat mutants by screening libraries of T-DNA insertion mutants and by using various “reverse genetic” approaches. These mutants disrupt expression of genes of numerous categories, including chromatin structural and remodeling genes, and genes encoding proteins implicated in nuclear targeting, cell wall structure and metabolism, cytoskeleton structure and function, and signal transduction. Here, we present an update on the identification and characterization of these rat mutants.

Characterization of the Arabidopsis Lysine-Rich Arabinogalactan-Protein AtAGP17 Mutant (rat1) That Results in a Decreased Efficiency of Agrobacterium Transformation

Arabinogalactan-proteins (AGPs) are a family of complex proteoglycans widely distributed in plants. The Arabidopsis rat1 mutant, previously characterized as resistant to Agrobacterium tumefaciens root transformation, is due to a mutation in the gene for the Lys-rich AGP, AtAGP17. We show that the phenotype of rat1 correlates with down-regulation of AGP17 in the root as a result of a T-DNA insertion into the promoter of AGP17. Complementation of rat1 plants by a floral dip method with either the wild-type AGP17 gene or cDNA can restore the plant to a wild-type phenotype in several independent transformants. Based on changes in PR1 gene expression and a decrease in free salicylic acid levels upon Agrobacterium infection, we suggest mechanisms by which AGP17 allows Agrobacterium rapidly to reduce the systemic acquired resistance response during the infection process.

IMPa-4, an Arabidopsis Importin α Isoform, Is Preferentially Involved in Agrobacterium-Mediated Plant Transformation

Successful transformation of plants by Agrobacterium tumefaciens requires that the bacterial T-complex actively escorts T-DNA into the hosts nucleus. VirD2 and VirE2 are virulence proteins on the T-complex that have plant-functional nuclear localization signal sequences that may recruit importin α proteins of the plant for nuclear import. In this study, we evaluated the involvement of seven of the nine members of the Arabidopsis thaliana importin α family in Agrobacterium transformation. Yeast two-hybrid, plant bimolecular fluorescence complementation, and in vitro protein–protein interaction assays demonstrated that all tested Arabidopsis importin α members can interact with VirD2 and VirE2. However, only disruption of the importin IMPa-4 inhibited transformation and produced the rat (resistant to Agrobacterium transformation) phenotype. Overexpression of six importin α members, including IMPa-4, rescued the rat phenotype in the impa-4 mutant background. Roots of wild-type and impa-4 Arabidopsis plants expressing yellow fluorescent protein–VirD2 displayed nuclear localization of the fusion protein, indicating that nuclear import of VirD2 is not affected in the impa-4 mutant. Somewhat surprisingly, VirE2–yellow fluorescent protein mainly localized to the cytoplasm of both wild-type and impa-4 Arabidopsis cells and to the cytoplasm of wild-type tobacco (Nicotiana tabacum) cells. However, bimolecular fluorescence complementation assays indicated that VirE2 could localize to the nucleus when IMPa-4, but not when IMPa-1, was overexpressed.

Novel Plant Transformation Vectors Containing the Superpromoter

We developed novel plasmids and T-DNA binary vectors that incorporate a modified and more useful form of the superpromoter. The superpromoter consists of a trimer of the octopine synthase transcriptional activating element affixed to the mannopine synthase2′ (mas2′) transcriptional activating element plus minimal promoter. We tested a superpromoter-β-glucuronidaseA fusion gene in stably transformed tobacco (Nicotiana tabacum) and maize (Zea mays) plants and in transiently transformed maize Black Mexican Sweet protoplasts. In both tobacco and maize, superpromoter activity was much greater in roots than in leaves. In tobacco, superpromoter activity was greater in mature leaves than in young leaves, whereas in maize activity differed little among the tested aerial portions of the plant. When compared with other commonly used promoters (cauliflower mosaic virus 35S, mas2′, and maize ubiquitin), superpromoter activity was approximately equivalent to those of the other promoters in both maize Black Mexican Sweet suspension cells and in stably transformed maize plants. The addition of a maize ubiquitin intron downstream of the superpromoter did not enhance activity in stably transformed maize.

Generation of Backbone-Free, Low Transgene Copy Plants by Launching T-DNA from the Agrobacterium Chromosome

In both applied and basic research, Agrobacterium-mediated transformation is commonly used to introduce genes into plants. We investigated the effect of three Agrobacterium tumefaciens strains and five transferred (T)-DNA origins of replication on transformation frequency, transgene copy number, and the frequency of integration of non-T-DNA portions of the T-DNA-containing vector (backbone) into the genome of Arabidopsis (Arabidopsis thaliana) and maize (Zea mays). Launching T-DNA from the picA locus of the Agrobacterium chromosome increases the frequency of single transgene integration events and almost eliminates the presence of vector backbone sequences in transgenic plants. Along with novel Agrobacterium strains we have developed, our findings are useful for improving the quality of T-DNA integration events.

Overexpression of Several Arabidopsis Histone Genes Increases Agrobacterium-Mediated Transformation and Transgene Expression in Plants

The Arabidopsis thaliana histone H2A-1 is important for Agrobacterium tumefaciens–mediated plant transformation. Mutation of HTA1, the gene encoding histone H2A-1, results in decreased T-DNA integration into the genome of Arabidopsis roots, whereas overexpression of HTA1 increases transformation frequency. To understand the mechanism by which HTA1 enhances transformation, we investigated the effects of overexpression of numerous Arabidopsis histones on transformation and transgene expression. Transgenic Arabidopsis containing cDNAs encoding histone H2A (HTA), histone H4 (HFO), and histone H3-11 (HTR11) displayed increased transformation susceptibility, whereas histone H2B (HTB) and most histone H3 (HTR) cDNAs did not increase transformation. A parallel increase in transient gene expression was observed when histone HTA, HFO, or HTR11 overexpression constructs were cotransfected with double- or single-stranded forms of a gusA gene into tobacco (Nicotiana tabacum) protoplasts. However, these cDNAs did not increase expression of a previously integrated transgene. We identified the N-terminal 39 amino acids of H2A-1 as sufficient to increase transient transgene expression in plants. After transfection, transgene DNA accumulates more rapidly in the presence of HTA1 than with a control construction. Our results suggest that certain histones enhance transgene expression, protect incoming transgene DNA during the initial stages of transformation, and subsequently increase the efficiency of Agrobacterium-mediated transformation.

Analysis of the gene cluster encoding carotenoid biosynthesis in Erwinia herbicola Eho13

Erwinia herbicola is known to synthesize carotenoids and gives an orange-coloured phenotype. These carotenoids play a role in the protection of the cells from the damage caused by near-UV irradiation in nature. The genes encoding these carotenoids in E. herbicola Eho13 are clustered in a 7 kb DNA fragment. The complete sequence of this fragment has been determined. DNA sequence analysis revealed that the entire sequence contains at least five genes, which are transcribed in the same direction. These five genes are organized in the order crtE-crtX-crtY-crtI-crtB. A gene fusion study showed that two different regions in this 7 kb gene cluster contain promoter activity. Primer-extension analysis identified two transcription start sites, located 147 bp upstream from the first gene of the cluster, crtE, and within the last gene of the cluster, crtB. An RNA-PCR study suggested that the five crt genes were organized in an operon and were transcribed from the promoter upstream from crtE.

Screening a cDNA Library for Protein–Protein Interactions Directly in Planta

This article presents a method to screen a plant cDNA library for genes encoding proteins that interact with a bait protein directly in plants using bimolecular fluorescence complementation technology. Proof-of-concept experiments identified both known and novel Arabidopsis thaliana proteins important for Agrobacterium-mediated plant transformation. Screening cDNA libraries for genes encoding proteins that interact with a bait protein is usually performed in yeast. However, subcellular compartmentation and protein modification may differ in yeast and plant cells, resulting in misidentification of protein partners. We used bimolecular fluorescence complementation technology to screen a plant cDNA library against a bait protein directly in plants. As proof of concept, we used the N-terminal fragment of yellow fluorescent protein– or nVenus-tagged Agrobacterium tumefaciens VirE2 and VirD2 proteins and the C-terminal extension (CTE) domain of Arabidopsis thaliana telomerase reverse transcriptase as baits to screen an Arabidopsis cDNA library encoding proteins tagged with the C-terminal fragment of yellow fluorescent protein. A library of colonies representing ∼2 × 105 cDNAs was arrayed in 384-well plates. DNA was isolated from pools of 10 plates, individual plates, and individual rows and columns of the plates. Sequential screening of subsets of cDNAs in Arabidopsis leaf or tobacco (Nicotiana tabacum) Bright Yellow-2 protoplasts identified single cDNA clones encoding proteins that interact with either, or both, of the Agrobacterium bait proteins, or with CTE. T-DNA insertions in the genes represented by some cDNAs revealed five novel Arabidopsis proteins important for Agrobacterium-mediated plant transformation. We also used this cDNA library to confirm VirE2-interacting proteins in orchid (Phalaenopsis amabilis) flowers. Thus, this technology can be applied to several plant species.

Cytokinins Secreted by Agrobacterium Promote Transformation by Repressing a Plant Myb Transcription Factor

Natural bacterial cytokinins may help engineer crops with improved characteristics. Virulent Secretions Put to Good Use Plant engineering uses bacteria to transform plants and improve characteristics, such as salt or drought tolerance, in economically important crops. Better known as plant hormones that stimulate growth, Sardesai et al. found that cytokinins secreted by the plant pathogen Agrobacterium tumefaciens promoted the transformation of Arabidopsis plants by inhibiting the expression of MTF1, which encodes a myb transcription factor, in the roots of the plants. Treating roots with trans-zeatin, for example, increased bacterial attachment and induced transformation even in normally resistant Arabidopsis ecotypes through the activities of specific cytokinin-responsive kinases and downstream regulators. Their findings indicate that exposing roots to certain Agrobacterium-secreted cytokinins may subvert a plant’s defenses to improve genetic transformation. Agrobacterium-mediated transformation is the most widely used technique for generating transgenic plants. However, many crops remain recalcitrant. We found that an Arabidopsis myb family transcription factor (MTF1) inhibited plant transformation susceptibility. Mutating MTF1 increased attachment of several Agrobacterium strains to roots and increased both stable and transient transformation in both susceptible and transformation-resistant Arabidopsis ecotypes. Cytokinins from Agrobacterium tumefaciens decreased the expression of MTF1 through activation of the cytokinin response regulator ARR3. Mutating AHK3 and AHK4, genes that encode cytokinin-responsive kinases, increased the expression of MTF1 and impaired plant transformation. Mutant mtf1 plants also had increased expression of AT14A, which encodes a putative transmembrane receptor for cell adhesion molecules. Plants overexpressing AT14A exhibited increased susceptibility to transformation, whereas at14a mutant plants exhibited decreased attachment of bacteria to roots and decreased transformation, suggesting that AT14A may serve as an anchor point for Agrobacteria. Thus, by promoting bacterial attachment and transformation of resistant plants and increasing such processes in susceptible plants, treating roots with cytokinins may help engineer crops with improved features or yield.