Kang Nam Kyu, Kim Eun Kyung, Kim Young Uk, Lee Bongsoo, Jeong Won-Joong, Jeong Byeong-Ryool, Chang Yong Keun
Department of Chemical and Biomolecular Engineering, KAIST, 291, Daehak-ro, Yuseong-gu, Daejeon, 34141 Republic of Korea.
Advanced Biomass R&D Center, 291, Daehak-ro, Yuseong-gu, Daejeon, 34141 Republic of Korea.
Biotechnol Biofuels. 2017 Oct 10;10:231. doi: 10.1186/s13068-017-0919-5. eCollection 2017.
Genetic engineering of microalgae is necessary to produce economically feasible strains for biofuel production. Current efforts are focused on the manipulation of individual metabolic genes, but the outcomes are not sufficiently stable and/or efficient for large-scale production of biofuels and other materials. Transcription factors (TFs) are emerging as good alternatives for engineering of microalgae, not only to increase production of biomaterials but to enhance stress tolerance. Here, we investigated an AP2 type TF Wrinkled1 in (AtWRI1) known as a key regulator of lipid biosynthesis in plants, and applied it to industrial microalgae, .
We expressed TF heterologously in named NsAtWRI1, in an effort to re-enact its key regulatory function of lipid accumulation. Stable integration was confirmed by RESDA PCR, and its expression was confirmed by Western blotting using the FLAG tag. Characterizations of transformants revealed that the neutral and total lipid contents were greater in NsAtWRI1 transformants than in WT under both normal and stress conditions from day 8. Especially, total lipid contents were 36.5 and 44.7% higher in NsAtWRI1 2-3 than in WT under normal and osmotic stress condition, respectively. FAME contents of NsAtWRI1 2-3 were also increased compared to WT. As a result, FAME yield of NsAtWRI1 2-3 was increased to 768 mg/L/day, which was 64% higher than that of WT under the normal condition. We identified candidates of AtWRI1-regulated genes by searching for the presence of the AW-box in promoter regions, among which lipid metabolic genes were further analyzed by qRT-PCR. Overall, qRT-PCR results on day 1 indicated that AtWRI1 down-regulated and , and up-regulated , , , and , resulting in enhanced lipid production in NsAtWRI1 transformants from early growth phase.
AtWRI1 TF regulated several genes involved in lipid synthesis in , resulting in enhancement of neutral lipid and FAME production. These findings suggest that heterologous expression of AtWRI1 TF can be utilized for efficient biofuel production in industrial microalgae.
微藻的基因工程对于生产经济可行的生物燃料菌株至关重要。目前的努力主要集中在单个代谢基因的操纵上,但对于生物燃料和其他材料的大规模生产而言,其结果的稳定性和/或效率还不够。转录因子(TFs)正成为微藻工程的良好替代方案,不仅可提高生物材料的产量,还能增强胁迫耐受性。在此,我们研究了一种AP2型TF——植物中已知的脂质生物合成关键调节因子皱叶1(AtWRI1),并将其应用于工业微藻。
我们在中异源表达TF,命名为NsAtWRI1,以重现其脂质积累的关键调节功能。通过RESDA PCR确认了稳定整合,并使用FLAG标签通过蛋白质印迹法确认了其表达。转化体的表征显示,从第8天起,在正常和胁迫条件下,NsAtWRI1转化体中的中性脂质和总脂质含量均高于野生型。特别是,在正常和渗透胁迫条件下,NsAtWRI1 2 - 3中的总脂质含量分别比野生型高36.5%和44.7%。与野生型相比,NsAtWRI1 2 - 3的脂肪酸甲酯(FAME)含量也有所增加。结果,NsAtWRI1 2 - 3的FAME产量提高到768毫克/升/天,在正常条件下比野生型高64%。我们通过在启动子区域搜索AW盒来鉴定AtWRI1调节基因的候选基因,其中脂质代谢基因通过qRT - PCR进一步分析。总体而言,第天的qRT - PCR结果表明,AtWRI1下调了和,并上调了、、和,从而导致NsAtWRI1转化体从早期生长阶段起脂质产量增加。
AtWRI1 TF调节了中几个参与脂质合成的基因,导致中性脂质和FAME产量增加。这些发现表明,AtWRI1 TF的异源表达可用于工业微藻的高效生物燃料生产。
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