Nitrogen Fertiliser Effects on Grain Anthocyanin and γ-Oryzanol Biosynthesis in Black Rice

Agriculture Pub Date : 2024-05-24 DOI:10.3390/agriculture14060817

Manisha Thapa, Lei Liu, Bronwyn J. Barkla, Tobias Kretzschmar, Suzy Y. Rogiers, Terry J. Rose

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Abstract

Accumulation of phytochemicals in vegetative tissue under nitrogen (N) stress as an adaptive strategy has been investigated in various crops, but the effect of applied N on grain phytochemicals is poorly understood. This study investigated the effect of applied N on the biosynthesis and accumulation of rice (Oryza sativa L.) grain anthocyanin and γ-oryzanol under different ultraviolet-B (UV-B) conditions in a controlled pot trial using two distinct black rice genotypes. The response of grain anthocyanin and γ-oryzanol content to applied N was genotype-dependent but was not altered by UV-B conditions. Applied N increased grain anthocyanin and decreased γ-oryzanol content in genotype SCU212 but had no significant effect in genotype SCU254. The expression of the OsKala3 regulatory gene was significantly upregulated in response to applied N in SCU212, while the expressions of OsKala4 and OsTTG1 were unchanged. The expression of all three regulatory genes was not significantly affected in SCU254 with applied N. Key anthocyanin biosynthesis genes were upregulated in grain by N application, which indicates that the common increase in anthocyanin in vegetative tissues under N deprivation does not hold true for reproductive tissues. Hence, any future approach to target higher content of these key phytochemicals in grains should be genotype-focused.

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氮肥对黑米籽粒花青素和γ-芳樟醇生物合成的影响

氮胁迫下植物组织中植物化学物质的积累作为一种适应策略已在多种作物中进行了研究，但对施用氮对谷物植物化学物质的影响却知之甚少。本研究利用两种不同的黑米基因型，在对照盆栽试验中研究了不同紫外线-B（UV-B）条件下施用氮对水稻（Oryza sativa L.）籽粒花青素和γ-oryzanol的生物合成和积累的影响。谷物花青素和 γ -oryzanol 含量对施用氮的反应取决于基因型，但紫外线-B 条件不会改变。施用氮能增加基因型 SCU212 的谷粒花青素含量，降低γ-芳唑醇含量，但对基因型 SCU254 没有显著影响。在 SCU212 中，OsKala3 调控基因的表达在施加氮条件下显著上调，而 OsKala4 和 OsTTG1 的表达则没有变化。施用氮素后，谷物中的关键花青素生物合成基因上调，这表明在氮素匮乏条件下营养组织中花青素增加的现象并不适用于生殖组织。因此，未来任何以提高谷物中这些关键植物化学物质含量为目标的方法都应该以基因型为重点。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Agriculture

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