Binary Bacterial Artificial Chromosome Vector Research Articles

Multigene Engineering in Rice Using High-Capacity Agrobacterium tumefaciens BIBAC Vectors.

The high-capacity binary bacterial artificial chromosome (BIBAC) vector system permits the insertion of large fragments of DNA, up to 150 kb, into plants via Agrobacterium-mediated transformation. Here, we describe an optimized protocol for transformation of japonica rice (Oryza sativa L.) using this system. Calli derived from mature embryos are transformed using Agrobacterium strain LBA4404 that carries the BIBAC vector and the super-virulent helper plasmid pCH32. Transformed calli are then regenerated using optimized media and tested for transgene integration by PCR, GUS assay, and Southern blot analyses.

Engineered Minichromosomes in Plants: Structure, Function, and Applications.

Engineered minichromosomes are small chromosomes that contain a transgene and selectable marker, as well as all of the necessary components required for maintenance in an organism separately from the standard chromosome set. The separation from endogenous chromosomes makes engineered minichromosomes useful in the production of transgenic plants. Introducing transgenes to minichromosomes does not have the risk of insertion within a native gene; additionally, transgenes on minichromosomes can be transferred between lines without the movement of linked genes. Of the two methods proposed for creating engineered minichromosomes, telomere-mediated truncation is more reliable in plant systems. Additionally, many plants contain a supernumerary, or B chromosome, which is an excellent starting material for minichromosome creation. The use of site-specific recombination systems in minichromosomes can increase their utility, allowing for the addition or subtraction of transgenes in vivo. The creation of minichromosomes with binary bacterial artificial chromosome vectors provides the ability to introduce many transgenes at one time. Furthermore, coupling minichromosomes with haploid induction systems can facilitate transfer between lines. Minichromosomes can be introduced to a haploid-inducing line and crossed to target lines. Haploids of the target line that then contain a minichromosome can then be doubled. These homozygous lines will contain the transgene without the need for repeated introgressions.

Genomic Resources for Gene Discovery, Functional Genome Annotation, and Evolutionary Studies of Maize and Its Close Relatives

Maize is one of the most important food crops and a key model for genetics and developmental biology. A genetically anchored and high-quality draft genome sequence of maize inbred B73 has been obtained to serve as a reference sequence. To facilitate evolutionary studies in maize and its close relatives, much like the Oryza Map Alignment Project (OMAP) (www.OMAP.org) bacterial artificial chromosome (BAC) resource did for the rice community, we constructed BAC libraries for maize inbred lines Zheng58, Chang7-2, and Mo17 and maize wild relatives Zea mays ssp. parviglumis and Tripsacum dactyloides. Furthermore, to extend functional genomic studies to maize and sorghum, we also constructed binary BAC (BIBAC) libraries for the maize inbred B73 and the sorghum landrace Nengsi-1. The BAC/BIBAC vectors facilitate transfer of large intact DNA inserts from BAC clones to the BIBAC vector and functional complementation of large DNA fragments. These seven Zea Map Alignment Project (ZMAP) BAC/BIBAC libraries have average insert sizes ranging from 92 to 148 kb, organellar DNA from 0.17 to 2.3%, empty vector rates between 0.35 and 5.56%, and genome equivalents of 4.7- to 8.4-fold. The usefulness of the Parviglumis and Tripsacum BAC libraries was demonstrated by mapping clones to the reference genome. Novel genes and alleles present in these ZMAP libraries can now be used for functional complementation studies and positional or homology-based cloning of genes for translational genomics.

A plant-transformation-competent BIBAC library of ginseng (Panax ginseng C. A. Meyer) for functional genomics research and characterization of genes involved in ginsenoside biosynthesis

Ginseng (Panax ginseng C. A. Mey.) is widely used as a major medicinal herb and as a feedstock for the medicine, beverage, food, cosmetic, etc. industries, in China and several other Asian countries. However, limited research has been accomplished into its genetics, genomics and breeding. To clone, characterize and utilize the genes of economic importance in the species, we have developed a large-insert plant-transformation-competent binary bacterial artificial chromosome (BIBAC) library for Jilin ginseng cv. Damaya. The library contains 141,312 clones, with an average insert size of 110 kb, each likely containing approximately 20–30 genes. The clones of the library have all been arrayed in 384-well microplates and permanently archived. We screened the library and identified BIBAC clones containing nine genes likely involved in the biosynthesis pathway of ginsenosides—the major medicinally effective compounds of ginseng—with approximately four BIBACs per gene. This result further verified the quality of the library and demonstrated its utility in cloning, characterization and utilization of economically important genes in ginseng. Furthermore, since the library is cloned in a plant-transformation-competent BIBAC vector (pCLD04541) that can be directly transformed in a variety of plants via both the Agrobacterium-mediated method and the particle bombardment method, we have also demonstrated the stability of large-insert ginseng DNA BIBACs in different Agrobacterium strains, which is crucial to large-insert BIBAC transformation in plants. Therefore, the Jilin ginseng BIBAC library provides resources and tools useful for functional genomics research, and cloning, characterization and utilization of economically important genes in the species.

Construction of BIBAC and BAC libraries from a variety of organisms for advanced genomics research

Large-insert BAC (bacterial artificial chromosome) and BIBAC (binary BAC) libraries are essential for modern genomics research for all organisms. We helped pioneer the BAC and BIBAC technologies, and by using them we have constructed hundreds of BAC and BIBAC libraries for different species of plants, animals, marine animals, insects, algae and microbes. These libraries have been used globally for different aspects of genomics research. Here we describe the procedure with the latest improvements that we have made and used for construction of BIBAC libraries. The procedure includes the preparation of BIBAC vectors, the preparation of clonable fragments of the desired size from the source DNA, the construction and transformation of BIBACs and, finally, the characterization and assembly of BIBAC libraries. We also specify the modifications necessary for construction of BAC libraries using the protocol. The entire protocol takes ∼7 d.

Characterization of a plant-transformation-ready large-insert BIBAC library ofArabidopsisand bombardment transformation of a large-insert BIBAC of the library into tobacco

Plant-transformation-ready, large-insert binary bacterial artificial chromosome (BIBAC) libraries are of significance for functional and network analysis of large genomic regions, gene clusters, large-spanning genes, and complex loci in the post-genome era. Here, we report the characterization of a plant-transformation-ready BIBAC library of the sequenced Arabidopsis genome for which such a library is not available to the public, the transformation of a large-insert BIBAC of the library into tobacco by biolistic bombardment, and the expression analysis of its containing genes in transgenic plants. The BIBAC library was constructed from nuclear DNA partially digested with BamHI in the BIBAC vector pCLD04541. It contains 6144 clones and has a mean insert size of 108kb, representing 5.2× equivalents of the Arabidopsis genome or a probability of greater than 99% of obtaining at least one positive clone from the library using a single-copy sequence as a probe. The transformation of the large-insert BIBAC and analyses of the transgenic plants showed that not only did transgenic plants have intact BIBAC DNA, but also could the BIBAC be transmitted stably into progenies and its containing genes be expressed actively. These results suggest that the large-insert BIBAC library, combined with the biolistic bombardment transformation method, could provide a useful tool for large-scale functional analysis of the Arabidopsis genome sequence and applications in plant-molecular breeding.

Introduction of large DNA inserts into the barley pathogenic fungus, Ustilago hordei, via recombined binary BAC vectors and Agrobacterium-mediated transformation

Genetic transformation of organisms with large genome fragments containing complete genes, with regulatory elements or clusters of genes, can contribute to the functional analysis of such genes. However, large inserts, such as those found on bacterial artificial chromosome (BAC) clones, are often not easy to transfer. We exploited an existing technique to convert BAC clones, containing genomic DNA fragments from the barley-covered smut fungus Ustilago hordei to binary BACs (BIBACs) to make them transferable by the Agrobacterium tumefaciens T-DNA transfer machinery. Genetic transformation of U. hordei with BAC clones using polyethylene glycol or electroporation is difficult. As a proof of concept, two BAC clones were successfully converted into BIBAC vectors and transferred by A. tumefaciens into U. hordei and U. maydis, the related corn smut fungi. Molecular analysis of the transformants showed that the T-DNA containing the BAC clones with their inserts was stably integrated into the U. hordei genome. A transformation frequency of approximately 10⁻⁴ was achieved both for U. hordei sporidia and protoplasts; the efficiencies were 25-30 times higher for U. maydis. The combination of in vivo recombineering technology for BAC clones and A. tumefaciens-mediated transformation of Ustilago species should pave the way for functional genomics studies.

Agrobacterium-Mediated Transformation of Large DNA Fragments Using a BIBAC Vector System in Rice

Large DNA fragments were transferred to rice (Oryza sativa L.) by an Agrobacterium-mediated transformation protocol using the binary bacterial artificial chromosome (BIBAC) vector system. Calli derived from mature embryos of japonica rice cultivar H1493 were used as target tissues. LBA4404 with the pCH32 helper plasmid carrying virE and virG was found to be the most efficient strain for the transfer of large DNA fragment into the rice genome. One notable difference between Agrobacterium-mediated transformation using standard binary vectors and that reported herein was that transformation using the BIBAC system required Agrobacterium tumefaciens carrying the virulence helper plasmid with virG/virE. Polymerase chain reaction, Southern blot, and progeny analyses confirmed the integration and inheritance of the insert fragment and marker genes carried by BIBAC in the T0, T1, and T2 generations of transgenic events. To our knowledge, this represents the first report in which fertile, stable transgenic rice has been produced using the BIBAC vector system. The transformation system developed here would be useful for transferring large DNA fragments and for cloning and functional analysis of genes in rice.

Construction of a genomic library of wild rice and Agrobacterium-mediated transformation of large insert DNA linked to BPH resistance locus

Here we report the first genomic library of wild rice constructed on a plant-transformation-competent binary vector (BIBAC2) and transformation of the large insert DNA into rice via Agrobacterium. We selected Oryza officinalis for genomic library construction. The library consists of 55,296 clones and stored in one hundred forty-four 384-well plates. Random sampling of 140 clones indicated an average insert size of 71 Kb at a range of 15–235 Kb and 4.8% empty vectors. Four wheat chloroplast probes and four maize mitochondrial probes were hybridized separately to the library, showing that contamination with organellar DNAs is very low (0.61% and 0.04%, respectively). The binary bacterial artificial chromosome (BIBAC) library provides 5.3 haploid genome equivalents, implying a 99.5% probability of recovering any specific sequence of interest. A stability test indicated that the large DNA inserts were stable in this BIBAC vector both in host cells of Escherichia coli and Agrobacterium. Two restriction-fragment length polymorphism (RFLP) markers R288 and C820, which co-segregate with brown planthopper (BPH) resistance gene Qbp2, were used to screen the library, and identified seven and eight positive clones, respectively. The candidate clones of target gene isolated from the library are directly used to transform cultivated rice. After screening the Agrobacterium strains and helper plasmids, and using an improved procedure of transformation, a BIBAC clone with 120 Kb O. officinalis DNA insert was successfully transferred into the rice genome via Agrobacterium-mediated transformation. The system developed here should serve as source for gene discovery, gene cloning and genome-related research in wild rice.

Development of a new transformation-competent artificial chromosome (TAC) vector and construction of tomato and rice TAC libraries

Recent research has shown that BIBAC (binary bacterial artificial chromosome) and TAC (transformation-competent artificial chromosome) vector systems are very useful tools for map-based cloning of agronomically important genes in plant species. We have developed a new TAC vector that is suitable for both dicot and monocot transformation. Using this new TAC vector, we constructed large-insert genomic libraries of tomato and rice. The tomato library contains 96,996 clones (28.3-38.5 kb insert size) and has 3.18 haploid genome equivalents. The rice TAC library has 32.7 kb average insert size and has 9.24 haploid genome equivalents. The quality of these two libraries was tested using PCR to verify genome coverage. Individual clones were characterized to confirm insert integrity by Southern analysis, end sequencing and genetic mapping. To investigate the potential application of these TAC libraries in map-based cloning, TAC constructs containing a 45 kb fragment were introduced into the rice genome via Agrobacterium-mediated transformation. Molecular analysis indicates that the 45 kb fragment was successfully transferred into the rice genome. Although rearrangements of the introduced DNA were detected, 50% of regenerated plants contained at least one intact copy of the 45 kb clone and associated vector sequences. These libraries provide us with a valuable resource to rapidly isolate important genes in tomato and rice.