Yu Dan, Hornung Ellen, Iven Tim, Feussner Ivo
1Department of Plant Biochemistry, Albrecht-von-Haller-Institute for Plant Sciences, University of Goettingen, Justus-von-Liebig-Weg 11, 37077 Goettingen, Germany.
2Department of Plant Biochemistry, Center for Molecular Biosciences (GZMB), University of Goettingen, Justus-von-Liebig-Weg 11, 37077 Goettingen, Germany.
Biotechnol Biofuels. 2018 Mar 1;11:53. doi: 10.1186/s13068-018-1057-4. eCollection 2018.
Biotechnology enables the production of high-valued industrial feedstocks from plant seed oil. The plant-derived wax esters with long-chain monounsaturated acyl moieties, like oleyl oleate, have favorite properties for lubrication. For biosynthesis of wax esters using acyl-CoA substrates, expressions of a fatty acyl reductase (FAR) and a wax synthase (WS) in seeds are sufficient.
For optimization of the enzymatic activity and subcellular localization of wax ester synthesis enzymes, two fusion proteins were created, which showed wax ester-forming activities in . To promote the formation of oleyl oleate in seed oil, WSs from (WSD1) and (WS2), as well as the two created fusion proteins were tested in Arabidopsis to evaluate their abilities and substrate preference for wax ester production. The tested seven enzyme combinations resulted in different yields and compositions of wax esters. Expression of a FAR of (FAR) with WSD1 or WS2 led to a high incorporation of C substrates in wax esters. The FAR/TMAWAT2-WSD1 combination resulted in the incorporation of more C alcohol and C acyl moieties into wax esters compared with FAR/WSD1. The fusion protein of a WS from (WS) with MaFAR exhibited higher specificity toward C substrates in preference to C substrates. Expression of FAR/WSD1 in the Arabidopsis double mutant resulted in the accumulation of oleyl oleate (18:1/18:1) in up to 62 mol% of total wax esters in seed oil, which was much higher than the 15 mol% reached by FAR/WSD1 in Arabidopsis Col-0 background. In order to increase the level of oleyl oleate in seed oil of , lines expressing FAR/WS were crossed with a transgenic high oleate line. The resulting plants accumulated up to >40 mg g seed of wax esters, containing 27-34 mol% oleyl oleate.
The overall yields and the compositions of wax esters can be strongly affected by the availability of acyl-CoA substrates and to a lesser extent, by the characteristics of wax ester synthesis enzymes. For synthesis of oleyl oleate in plant seed oil, appropriate wax ester synthesis enzymes with high catalytic efficiency and desired substrate specificity should be expressed in plant cells; meanwhile, high levels of oleic acid-derived substrates need to be supplied to these enzymes by modifying the fatty acid profile of developing seeds.
生物技术能够从植物种子油中生产高价值的工业原料。具有长链单不饱和酰基部分的植物衍生蜡酯,如油酸油酸酯,具有理想的润滑性能。对于使用酰基辅酶A底物生物合成蜡酯,种子中脂肪酸酰基还原酶(FAR)和蜡合酶(WS)的表达就足够了。
为了优化蜡酯合成酶的酶活性和亚细胞定位,构建了两种融合蛋白,它们在……中显示出蜡酯形成活性。为了促进种子油中油酸油酸酯的形成,对来自……(WSD1)和……(WS2)的蜡合酶以及两种构建的融合蛋白在拟南芥中进行了测试,以评估它们产生蜡酯的能力和底物偏好。测试的七种酶组合导致了蜡酯的不同产量和组成。……(FAR)的FAR与WSD1或WS2的表达导致蜡酯中C底物的高掺入。与FAR/WSD1相比,FAR/TMAWAT2-WSD1组合导致更多的C醇和C酰基部分掺入蜡酯中。来自……(WS)的蜡合酶与MaFAR的融合蛋白对C底物表现出比对C底物更高的特异性。FAR/WSD1在拟南芥……双突变体中的表达导致种子油中油酸油酸酯(18:1/18:1)在总蜡酯中积累高达62摩尔%,这远高于FAR/WSD1在拟南芥Col-0背景中达到的15摩尔%。为了提高……种子油中油酸油酸酯的水平,将表达FAR/WS的株系与转基因高油酸株系杂交。所得植物积累了高达>40mg g种子的蜡酯,其中含有27-34摩尔%的油酸油酸酯。
蜡酯的总产量和组成会受到酰基辅酶A底物可用性的强烈影响,在较小程度上也会受到蜡酯合成酶特性的影响。为了在植物种子油中合成油酸油酸酯,应在植物细胞中表达具有高催化效率和所需底物特异性的合适蜡酯合成酶;同时,需要通过改变发育种子的脂肪酸谱向这些酶提供高水平的油酸衍生底物。
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