Abstract
Rice is an important global crop and represents a vital source of calories for many food insecure regions. Efforts to improve this crop by improving yield, nutritional content, stress tolerance, or resilience to climate change are certain to include biotechnological approaches, which rely on the expression of transgenes in planta. The throughput and cost of currently available transgenic expression systems is frequently incompatible with modern, high‐throughput molecular cloning methods. Here, we present a protocol for isolating high yields of green rice protoplasts and for PEG‐mediated transformation of isolated protoplasts. Factors affecting transformation efficiency were investigated, and the resulting protocol is fast, cheap, robust, high‐throughput, and does not require specialist equipment. When coupled to a high‐throughput modular cloning system such as Golden Gate, this transient expression system provides a valuable resource to help break the “design‐build‐test” bottleneck by permitting the rapid screening of large numbers of transgenic expression cassettes prior to stable plant transformation. We used this system to rapidly assess the expression level, subcellular localisation, and protein aggregation pattern of nine single‐gene expression cassettes, which represent the essential component parts of the β‐cyanobacterial carboxysome.
Highlights
The plant science community is currently faced with many “grand challenges.” These include attaining sustainable global food security, ensuring crops are resilient to climate change, and restoring ecosystems (Huber, 2011)
Many transient expression platforms for crop species currently rely on the soil bacterium Agrobacterium tumefaciens to deliver expression cassettes located on T‐DNA into plant nuclei (Andrieu et al, 2012; Bhaskar, Venkateshwaran, Wu, Ané, & Jiang, 2009; Panwar, McCallum, & Bakkeren, 2013)
Transient expression of β‐cyanobacterial carboxysome genes using protoplasts confirmed that all nine proteins were successfully targeted to rice chloroplasts because yellow fluorescent protein (YFP) signal colocalised with chlorophyll autofluorescence in each case
Summary
Many transient expression platforms for crop species currently rely on the soil bacterium Agrobacterium tumefaciens ( known as Rhizobium radiobacter) to deliver expression cassettes located on T‐DNA into plant nuclei (Andrieu et al, 2012; Bhaskar, Venkateshwaran, Wu, Ané, & Jiang, 2009; Panwar, McCallum, & Bakkeren, 2013). While these methods can confer suitable levels of transgene expression in planta, they are low‐throughput and often require tissue from mature plants, increasing the growth space required and the time taken to acquire data. Plants were allowed to grow for 7 days after germination (Figure 1a)
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