Yoichi Ogawa

Efficient and High-Throughput Vector Construction and Agrobacterium-Mediated Transformation of Arabidopsis thaliana Suspension-Cultured Cells for Functional Genomics

We established a large-scale, high-throughput protocol to construct Arabidopsis thaliana suspension-cultured cell lines, each of which carries a single transgene, using Agrobacterium-mediated transformation. We took advantage of RIKEN Arabidopsis full-length (RAFL) cDNA clones and the Gateway cloning system for high-throughput preparation of binary vectors carrying individual full-length cDNA sequences. Throughout all cloning steps, multiple-well plates were used to treat 96 samples simultaneously in a high-throughput manner. The optimal conditions for Agrobacterium-mediated transformation of 96 independent binary vector constructs were established to obtain transgenic cell lines efficiently. We evaluated the protocol by generating transgenic Arabidopsis T87 cell lines carrying individual 96 metabolism-related RAFL cDNA fragments, and showed that the protocol was useful for high-throughput and large-scale production of gain-of-function lines for functional genomics.

High-throughput Cryopreservation of Plant Cell Cultures for Functional Genomics

Suspension-cultured cell lines from plant species are useful for genetic engineering. However, maintenance of these lines is laborious, involves routine subculturing and hampers wider use of transgenic lines, especially when many lines are required for a high-throughput functional genomics application. Cryopreservation of these lines may reduce the need for subculturing. Here, we established a simple protocol for cryopreservation of cell lines from five commonly used plant species, Arabidopsis thaliana, Daucus carota, Lotus japonicus, Nicotiana tabacum and Oryza sativa. The LSP solution (2 M glycerol, 0.4 M sucrose and 86.9 mM proline) protected cells from damage during freezing and was only mildly toxic to cells kept at room temperature for at least 2 h. More than 100 samples were processed for freezing simultaneously. Initially, we determined the conditions for cryopreservation using a programmable freezer; we then developed a modified simple protocol that did not require a programmable freezer. In the simple protocol, a thick expanded polystyrene (EPS) container containing the vials with the cell–LSP solution mixtures was kept at −30°C for 6 h to cool the cells slowly (pre-freezing); samples from the EPS containers were then plunged into liquid nitrogen before long-term storage. Transgenic Arabidopsis cells were subjected to cryopreservation, thawed and then re-grown in culture; transcriptome and metabolome analyses indicated that there was no significant difference in gene expression or metabolism between cryopreserved cells and control cells. The simplicity of the protocol will accelerate the pace of research in functional plant genomics.

A non-destructive screenable marker, OsFAST, for identifying transgenic rice seeds.

The production of transgenic plants has contributed greatly to plant research. Previously, an improved method for screening transgenic Arabidopsis thaliana seeds using the FAST (Fluorescence-Accumulating-Seed Technology) method and FAST marker was reported. Arabidopsis seeds containing the FAST marker may be visually screened using a fluorescence stereomicroscope or blue LED handy-type instrument. Although the FAST method was originally designed for Arabidopsis screens, this study endeavors to adapt this method for the screening of other plants. Here, an optimized technology, designated the OsFAST method, is presented as a useful tool for screening transgenic rice seeds. The OsFAST method is based on the expression of the OsFAST-G marker under the control of a seed-embryo-specific promoter, similar to the Arabidopsis FAST-G marker. The OsFAST method provides a simple and non-destructive method for identifying transgenic rice seeds. It is proposed that the FAST method is adaptable to various plant species and will enable a deeper analysis of the floral-dip method.