Identification of target genes and processes involved in erucic acid accumulation during seed development in the biodiesel feedstock Pennycress (Thlaspi arvense L.)
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- 作者:Ana Clavera ; Raquel Reyb ; M. Victoria Ló ; pezc ; Rafael Picorela ; Miguel Alfonsoa ; alfonso@eead.csic.es
- 关键词:Thlaspi arvense ; Erucic acid ; Seed oil ; TAG (triacylglycerol) ; FAE1 (fatty acid elongase 1) ; Biofuel
- 刊名:Journal of Plant Physiology
- 出版年:2017
- 出版时间:January 2017
- 年:2017
- 卷:208
- 期:Complete
- 页码:7-16
- 全文大小:2290 K
- 卷排序:208
文摘
We studied erucic acid accumulation in the biodiesel feedstock Pennycress (Thlaspi arvense L.) as a first step towards the development of a sustainable strategy for biofuel production in the EU territory. To that end, two inbred Pennycress lines of European origin, “NASC” and “French,” were cultivated in a controlled chamber and in experimental field plots, and their growth, seed production and seed oil characteristics analyzed. Differences in some agronomical traits like vernalization (winter-French versus spring-NASC), flowering time (delayed in the French line) and seed production (higher in the French line) were detected. Both lines showed a high amount (35–39%) of erucic acid (22:1Δ13) in their seed oil. Biochemical characterization of the Pennycress seed oil indicated that TAG was the major reservoir of 22:1Δ13. Incorporation of 22:1Δ13 to TAG occurred very early during seed maturation, concomitant with a decrease of desaturase activity. This change in the acyl fluxes towards elongation was controlled by different genes at different levels. TaFAE1 gene, encoding the fatty acid elongase, seemed to be controlled at the transcriptional level with high expression at the early stages of seed development. On the contrary, the TaFAD2 gene that encodes the Δ12 fatty acid desaturase or TaDGAT1 that catalyzes TAG biosynthesis were controlled post-transcriptionally. TaWRI1, the master regulator of seed-oil biosynthesis, showed also high expression at the early stages of seed development. Our data identified genes and processes that might improve the biotechnological manipulation of Pennycress seeds for high-quality biodiesel production.