Abstract
Using transgenic rice as a bioreactor for mass production of pharmaceutical proteins could potentially reduce the cost of production significantly. However, a major concern over the bioreactor transgenic rice is the risk of its unintended spreading into environment and into food or feed supplies. Here we report a mitigating method to prevent unwanted transgenic rice spreading by a double built-in containment strategy, which sets a selectively termination method and a visual tag technology in the T-DNA for transformation. We created transgenic rice with an inserted T-DNA that harbors a human proinsulin gene fused with the far-red fluorescent protein gene mKate_S158A, an RNAi cassette suppressing the expression of the rice bentazon detoxification enzyme CYP81A6, and an EPSPS gene as the selection marker for transformation. Herbicide spray tests indicated that such transgenic rice plants can be killed selectively by a spray of bentazon at regular field application dosage for rice weed control. Moreover, the transgenic rice seeds were bright red in color due to the fused far-red fluorescent protein, and could be easily visualized under daylight by naked eyes. Thus, the transgenic rice plants reported in this study could be selectively killed by a commonly used herbicide during their growth stage, and their seeds may be detected visually during processing and consumption after harvest. This double built-in containment strategy may greatly enhance the confinement of the transgenic rice.
Highlights
Transgenic plant as a bioreactor has been presented as a cost effective platform to produce valuable proteins at a large scale [1]
A variety of recombinant proteins have been successfully expressed in rice seeds, including human lactoferrin [14], human serum albumin [5, 15], lipase [6], and modified hepatitis B virus surface antigen gene SS1 [16]
To create the transgenic rice bioreactor with a double built-in containment strategy, a binary T-DNA transformation plasmid was constructed based on pCAMBIA1300
Summary
Transgenic plant as a bioreactor has been presented as a cost effective platform to produce valuable proteins at a large scale [1]. Since the first proof-of-concept report on using plant as a protein expression bioreactor nearly 25 years ago [2], the utility of genetically modified (GM) plants has been expanded to serve as a general platform for the large-scale production of recombinant pharmaceutical proteins and industrial enzymes [3,4,5,6]. Rice shares the advantages of cereal seed bioreactor such as high grain yield, ease of transformation, and ease of scale-up [11, 12]. A variety of recombinant proteins have been successfully expressed in rice seeds, including human lactoferrin [14], human serum albumin [5, 15], lipase [6], and modified hepatitis B virus surface antigen gene SS1 [16]
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