Abstract
The castor oil plant represents a promising platform to produce oils with industrial applications. However, its use in biotechnology is limited by the absence of a well-established procedure to transform it, and a poor understanding of gene regulation and promoter use in this species. As such, a method has been developed to express proteins or hairpin-RNA in this plant, a method based on the direct injection of Agrobacterium into the developing endosperm of castor oil fruit, enabling different constructs and promoters to be tested. This method produces a high rate of transformation and a good proportion of viable seeds that express reporter genes for up to 20 days after infiltration (DAI). Gene expression under the control of different promoters was tested by quantitative real-time polymerase chain reaction and by directly assaying the activity of the galactouronidase reporter gene, which proved to be strongest when driven by the glycinin promoter. Constructs expressing a fatty acid elongase from Lesquerella fendleri were tested, the expression of which provoked an important increase in the lesquerolic acid in the castor oil endosperm at 5 and 10 DAI, although this fatty acid did not accumulate significantly in the final mature seeds. The nature of this response could reflect the poor availability of substrates for this enzyme. In the light of this data, the potential of this technique to test promoters and different constructs in castor oil plants and other oilseeds is discussed.
Highlights
Castor (Ricinus comunis) seed oil differs from other vegetable oils as it accumulates large amounts of the hydroxylated ricinoleic acid (12-hydroxyl-octadecen-9-oic acid, 18:1-OH) in its triacylglycerols (TAGs)
In the castor oil plant, the first stage occurs from day 1 to 10 after pollination (DAP) and the second one from 20 to 50 day to after pollination (DAP), which is subsequently followed by the final drying stage (Sánchez-García et al, 2010)
The vector used to study the efficiency of transformation was the pCAMBIA 1305.1, which contains a GUS reporter gene under the control of the strong constitutive CaMV 35S cauliflower mosaic virus (35S) promoter from cauliflower mosaic virus (35S: see Supplementary Figure 1)
Summary
Castor (Ricinus comunis) seed oil differs from other vegetable oils as it accumulates large amounts (up to 90%) of the hydroxylated ricinoleic acid (12-hydroxyl-octadecen-9-oic acid, 18:1-OH) in its triacylglycerols (TAGs). Non-edible, it has largely been used in cosmetics and medicine, and it is considered an important raw material for oleochemistry, as ricinoleic acid confers. The methyl ester of ricinoleic acid can be cracked to produce undecylenic acid, a precursor of nylon-11, and heptanal, an ingredient of perfumes and essences (Das et al, 1989). It is a substrate for the production of sebacic acid and 2-octanol, which have similar applications. Ricinoleic acid is the precursor of many greases and biolubricants, and it is used to produce biobased coatings and biofuels (Dwivedi and Sapre, 2002; Berman et al, 2011; Thakur and Karak, 2013)
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