Direct delivery and fast-treated Agrobacterium co-culture (Fast-TrACC) plant transformation methods for Nicotiana benthamiana.

There is an expanding need to modify plant genomes to create new plant germplasm that advances both basic and applied plant research. Most current methods for plant genome modification involve regenerating plants from genetically modified cells in tissue culture, which is technically challenging, expensive and time consuming, and works with limited plant species or genotypes. Herein, we describe two Agrobacterium-based methods for creating genetic modifications on either sterilely grown or soil-grown Nicotiana benthamiana plants. These methods use developmental regulators (DRs), gene products that influence cell division and differentiation, to induce de novo meristems. Genome editing reagents, such as the RNA-guided endonuclease Cas9, may be co-delivered with the DRs to create shoots that transmit edits to the next generation. One method, called fast-treated Agrobacterium co-culture (Fast-TrACC), delivers DRs to seedlings grown aseptically; meristems that produce shoots and ultimately whole plants are induced. The other approach, called direct delivery (DD), involves delivering DRs to soil-grown plants from which existing meristems have been removed; the DRs promote the formation of new shoots at the wound site. With either approach, if transgene cassettes and/or gene editing reagents are provided, these induced, de novo meristems may be transgenic, edited or both. These two methods offer alternative approaches for generating novel plant germplasm that are cheaper and less technically challenging and take less time than standard approaches. The whole procedure from transfer DNA (T-DNA) assembly to recovery of edited plants can be completed in ~70 d for both DD and Fast-TrACC.

An extensible vector toolkit and parts library for advanced engineering of plant genomes.

Plant biotechnology is rife with new advances in transformation and genome engineering techniques. A common requirement for delivery and coordinated expression in plant cells, however, places the design and assembly of transformation constructs at a crucial juncture as desired reagent suites grow more complex. Modular cloning principles have simplified some aspects of vector design, yet many important components remain unavailable or poorly adapted for rapid implementation in biotechnology research. Here, we describe a universal Golden Gate cloning toolkit for vector construction. The toolkit chassis is compatible with the widely accepted Phytobrick standard for genetic parts, and supports assembly of arbitrarily complex T-DNAs through improved capacity, positional flexibility, and extensibility in comparison to extant kits. We also provision a substantial library of newly adapted Phytobricks, including regulatory elements for monocot and dicot gene expression, and coding sequences for genes of interest such as reporters, developmental regulators, and site-specific recombinases. Finally, we use a series of dual-luciferase assays to measure contributions to expression from promoters, terminators, and from cross-cassette interactions attributable to enhancer elements in certain promoters. Taken together, these publicly available cloning resources can greatly accelerate the testing and deployment of new tools for plant engineering.

Site-specific recombinase genome engineering toolkit in maize.

Site-specific recombinase enzymes function in heterologous cellular environments to initiate strand-switching reactions between unique DNA sequences termed recombinase binding sites. Depending on binding site position and orientation, reactions result in integrations, excisions, or inversions of targeted DNA sequences in a precise and predictable manner. Here, we established five different stable recombinase expression lines in maize through Agrobacterium-mediated transformation of T-DNA molecules that contain coding sequences for Cre, R, FLPe, phiC31 Integrase, and phiC31 excisionase. Through the bombardment of recombinase activated DsRed transient expression constructs, we have determined that all five recombinases are functional in maize plants. These recombinase expression lines could be utilized for a variety of genetic engineering applications, including selectable marker removal, targeted transgene integration into predetermined locations, and gene stacking.

BiBAC Modification and Stable Transfer into Maize (Zea mays) Hi-II Immature Embryos via Agrobacterium-Mediated Transformation.

Binary Bacterial Artificial Chromosomes (BiBAC) are large insert cloning vectors that contain the necessary features required for Agrobacterium-mediated transformation. However, the large size of BiBACs and low-copy number in Escherichia coli (DH10B) and Agrobacterium tumefaciens make cloning experiments more difficult than other available binary vector systems. Therefore, a protocol that outlines preparation, modification, and transformation of high-molecular weight (HMW) constructs is advantageous for researchers looking to use BiBACs in plant genomics research. This unit does not cover the cloning of HMW DNA into BiBAC vectors. Researchers looking to clone HMW DNA into BiBACs can refer to Zhang et al. (2012; doi: 10.1038/nprot.2011.456). © 2017 by John Wiley & Sons, Inc.

Plant minichromosomes.

Plant minichromosomes have the potential for stacking multiple traits on a separate entity from the remainder of the genome. Transgenes carried on an independent chromosome would facilitate conferring many new properties to plants and using minichromosomes as genetic tools. The favored method for producing plant minichromosomes is telomere-mediated chromosomal truncation because the epigenetic nature of centromere function prevents using centromere sequences to confer the ability to organize a kinetochore when reintroduced into plant cells. Because haploid induction procedures are not always complete in eliminating one parental genome, chromosomes from the inducer lines are often present in plants that are otherwise haploid. This fact suggests that minichromosomes could be combined with doubled haploid breeding to transfer stacked traits more easily to multiple lines and to use minichromosomes for massive scale genome editing.

Telomere-Mediated Chromosomal Truncation for Generating Engineered Minichromosomes in Maize.

Minichromosomes have been generated in maize using telomere-mediated truncation. Telomere DNA, because of its repetitive nature, can be difficult to manipulate. The protocols in this unit describe two methods for generating the telomere DNA required for the initiation of telomere-mediated truncation. The resulting DNA can then be used with truncation cassettes for introduction into maize via transformation. © 2016 by John Wiley & Sons, Inc.

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.