The effect of light conditions on interpreting oil composition engineering in Arabidopsis seeds

Arabidopsis thaliana is the most developed and utilized model plant. In particular, it is an excellent model for proof‐of‐concept seed oil engineering studies because it accumulates approximately 37% seed oil by weight, and it is closely related to important Brassicaceae oilseed crops. Arabidopsis c...

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Bibliographic Details
Published in:Plant direct 2018-06, Vol.2 (6), p.e00067-n/a
Main Authors: Karki, Nischal, Bates, Philip D.
Format: Article
Language:English
Subjects:
Arabidopsis
Crops
Engineering
Enzymes
Fatty acid composition
Fatty acids
hydroxylated fatty acids
Laboratories
Light
Lipids
Metabolism
Oils & fats
Oilseeds
Original Research
ricinoleate
Seeds
triacylglycerol
Vitamin E
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Summary:Arabidopsis thaliana is the most developed and utilized model plant. In particular, it is an excellent model for proof‐of‐concept seed oil engineering studies because it accumulates approximately 37% seed oil by weight, and it is closely related to important Brassicaceae oilseed crops. Arabidopsis can be grown under a wide variety of conditions including continuous light; however, the amount of light is strongly correlated with total seed oil accumulation. In addition, many attempts to engineer novel seed oil fatty acid compositions in Arabidopsis have reported significant reductions in oil accumulation; however, the relative reduction from the nontransgenic controls varies greatly within the literature. A set of experiments were conducted to systematically analyze the effect of light conditions (including day/night cycle vs. continuous light, and different light intensities) on the relative accumulation of seed oil between three different transgenic lines producing novel hydroxy fatty acids and their nontransgenic background. Oil content was measured per seed and as a percentage of seed weight. Our results indicate the relative amount of seed oil between transgenic lines and nontransgenic controls is dependent on both the light conditions and the type of oil content measurement utilized. In addition, the light conditions effect the relative accumulation of the novel fatty acids between various transgenic lines. Therefore, the success of novel fatty acid proof‐of‐concept engineering strategies on both oil accumulation and fatty acid composition in Arabidopsis seeds should be considered in light of the select growth and measurement conditions prior to moving engineering strategies into crop plants.
ISSN:2475-4455
2475-4455
DOI:10.1002/pld3.67