Fei Zhou, Yan Liu, Pengyuan Xie, Jun Ma, Jing Wang, Jing Sun, Xutang Huang, Wenjun Wang
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Ultimately, 592 differentially expressed proteins (DEPs) (233 upregulated, 359 downregulated) were identified between high-oleate (‘L-1-OL-1’) and low-oleate (‘86–1’) maintainer lines. KEGG enrichment analysis of DEPs identified biosynthesis of unsaturated FAs as the most highly enriched biological pathway. Subsequently, combined transcriptome and proteome analysis results suggested that several proteins in this pathway might influence final seed OA content, including FAD2 (Δ12 fatty acid desaturase). Notably, FAD2 expression was significantly downregulated in ‘L-1-OL-1’ versus ‘86–1’ seeds, with results aligning with <i>FAD2</i> mRNA expression results determined via qRT-PCR analysis. 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引用次数: 0
摘要
作为一种重要的油料作物,向日葵(Helianthus annuus L.)含有大量不饱和脂肪酸(FAs)。葵花籽油中的不饱和脂肪酸主要包括油酸(OA,C18:1)和亚油酸(LOA,C18:2)。油酸的抗氧化活性使葵花籽油具有很高的健康价值,并适合储存。然而,高油酸和低油酸向日葵品种在种子发育过程中 OA 积累差异的分子机制仍有待探索。在此,为了鉴定与 OA 合成相关的关键蛋白,研究人员采用了相对和绝对定量的等位标记(iTRAQ)方法。最终,在高油酸('L-1-OL-1')和低油酸('86-1')保持系之间鉴定出了 592 个差异表达蛋白(DEPs)(233 个上调,359 个下调)。DEPs 的 KEGG 富集分析表明,不饱和脂肪酸的生物合成是富集程度最高的生物途径。随后,转录组和蛋白质组的综合分析结果表明,该途径中的几个蛋白质可能会影响种子最终的 OA 含量,其中包括 FAD2(Δ12 脂肪酸去饱和酶)。值得注意的是,与'86-1'种子相比,'L-1-OL-1'种子中 FAD2 的表达明显下调,其结果与通过 qRT-PCR 分析确定的 FAD2 mRNA 表达结果一致。这些发现以及对 OA 合成机制的了解有助于通过向日葵育种和基于种质的努力提高油质。
Identification of candidate proteins related to oleic acid accumulation during sunflower (Helianthus annuus L.) seed development through comparative proteome analysis
As a crucial oil crop, sunflower (Helianthus annuus L.) has a high content of unsaturated fatty acids (FAs). The unsaturated FAs found in sunflower oil mainly include oleic acid (OA, C18:1) and linoleic acid (LOA, C18:2). OA’s antioxidant activity makes sunflower oil with high health value and suitable for storage. However, molecular mechanisms underlying differences in OA accumulation between high- and low-oleate sunflower varieties in seed development remain unexplored. Here, to identify key OA synthesis-related proteins, isobaric tag for relative and absolute quantitation (iTRAQ) was performed. Ultimately, 592 differentially expressed proteins (DEPs) (233 upregulated, 359 downregulated) were identified between high-oleate (‘L-1-OL-1’) and low-oleate (‘86–1’) maintainer lines. KEGG enrichment analysis of DEPs identified biosynthesis of unsaturated FAs as the most highly enriched biological pathway. Subsequently, combined transcriptome and proteome analysis results suggested that several proteins in this pathway might influence final seed OA content, including FAD2 (Δ12 fatty acid desaturase). Notably, FAD2 expression was significantly downregulated in ‘L-1-OL-1’ versus ‘86–1’ seeds, with results aligning with FAD2 mRNA expression results determined via qRT-PCR analysis. These findings and understanding of OA synthesis mechanisms could help improve oil quality through breeding and germplasm-based efforts in sunflower.
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