敲除衣藻中的羧基转移酶互作因子 1 (CTI1),可将含油量提高五倍,且不影响细胞生长

Zhongze Li, Minjae Kim, Jose Robert da Silva Nascimento, Bertrand Legeret, Gabriel Lemes Jorge, Marie Bertrand, Frederic Beisson, Jay J. Thelen, Yonghua Li-Beisson
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摘要

叶绿体从头合成脂肪酸的第一步是由乙酰-CoA 羧化酶(ACCase)催化的。作为该途径的限速步骤,ACCase 受到正反两方面的调控。在这项研究中,我们鉴定了植物羧基转移酶互作因子1(CrCTI1)的衣藻同源物,并通过酵母双杂交蛋白-蛋白互作实验证明了该蛋白与ACC酶的α-羧基转移酶(Cra-CT)亚基的相互作用。三个独立的 CRISPR-Cas9 介导的 CrCTI1 基因敲除突变体都产生了增强的油脂表型,总脂肪酸累积量增加了 25%,脂滴中储存的三酰甘油(TAG)增加了五倍。crcti1 突变体的 TAG 表型不受光照影响,但会受到营养生长条件的影响。通过在异养条件下培养细胞,我们观察到了 CrCTI1 在平衡脂质积累和细胞生长方面的关键功能。将先前绘制的一个体内磷酸化位点(CrCTI1 Ser108 突变为 Ala 或 Asp)并不影响与 Cra-CT 的相互作用。然而,将 Cra-CT 中所有六个预测的磷酸化位点突变为拟磷突变体,则会显著降低这种配对相互作用。对 crcti1 突变体和 WT 的比较蛋白质组分析表明,CrCTI1 通过协调碳代谢、抗氧化和脂肪酸 beta 氧化途径,在调节碳通量方面发挥作用,使细胞能够适应碳的供应。综上所述,这项研究确定了 CrCTI1 是藻类脂肪酸合成的负调控因子,并为用于生物技术目的的微藻类基因工程提供了一块新的分子砖。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Knocking out the carboxyltransferase interactor 1 (CTI1) in Chlamydomonas boosted oil content by fivefold without affecting cell growth
The first step in chloroplast de novo fatty acid synthesis is catalyzed by acetyl-CoA carboxylase (ACCase). As the rate-limiting step for this pathway, ACCase is subject to both positive and negative regulation. In this study, we identify a Chlamydomonas homolog of the plant carboxyltransferase interactor 1 (CrCTI1) and show that this protein, interacts with the Chlamydomonas alpha-carboxyltransferase (Cra-CT) subunit of the ACCase by yeast two-hybrid protein-protein interaction assay. Three independent CRISPR-Cas9 mediated knock-out mutants for CrCTI1 each produced an enhanced-oil phenotype, accumulating 25% more total fatty acids and storing up to five-fold more triacylglycerols (TAGs) in lipid droplets. The TAG phenotype of the crcti1 mutants was not influenced by light but was affected by trophic growth conditions. By growing cells under heterotrophic conditions, we observed a crucial function of CrCTI1 in balancing lipid accumulation and cell growth. Mutating a previously mapped in vivo phosphorylation site (CrCTI1 Ser108 to either Ala or to Asp), did not affect the interaction with Cra-CT. However, mutating all six predicted phosphorylation sites within Cra-CT to create a phosphomimetic mutant reduced significantly this pairwise interaction. Comparative proteomic analyses of the crcti1 mutants and WT suggested a role for CrCTI1 in regulating carbon flux by coordinating carbon metabolism, antioxidant and fatty acid beta-oxidation pathways, to enable cells adapt to carbon availability. Taken together, this study identifies CrCTI1 as a negative regulator of fatty acid synthesis in algae and provides a new molecular brick for genetic engineering of microalgae for biotechnology purposes.
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