Metabolic and molecular mechanisms of spine color formation in Chinese red chestnut

Frontiers in Plant Science Pub Date : 2024-05-21 DOI:10.3389/fpls.2024.1377899

Qian Qiao, Yun Gao, Qingzhong Liu

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Abstract

The spines of Chinese red chestnut are red and the depth of their color gradually increases with maturity. To identify the anthocyanin types and synthesis pathways in red chestnut and to identify the key genes regulating the anthocyanin biosynthesis pathway, we obtained and analyzed the transcriptome and anthocyanin metabolism of red chestnut and its control variety with green spines at 3 different periods. GO and KEGG analyses revealed that photosynthesis was more highly enriched in green spines compared with red spines, while processes related to defense and metabolism regulation were more highly enriched in red spines. The analysis showed that the change in spine color promoted photoprotection in red chestnut, especially at the early growth stage, which resulted in the accumulation of differentially expressed genes involved in the defense metabolic pathway. The metabolome results revealed 6 anthocyanins in red spines. Moreover, red spines exhibited high levels of cyanidin, peonidin and pelargonidin and low levels of delphinidin, petunidin and malvidin. Compared with those in the control group, the levels of cyanidin, peonidin, pelargonidin and malvidin in red spines were significantly increased, indicating that the cyanidin and pelargonidin pathways were enriched in the synthesis of anthocyanins in red spines, whereas the delphinidin pathways were inhibited and mostly transformed into malvidin. During the process of flower pigment synthesis, the expression of the CHS, CHI, F3H, CYP75A, CYP75B1, DFR and ANS genes clearly increased, that of CYP73A decreased obviously, and that of PAL, 4CL and LAR both increased and decreased. Notably, the findings revealed that the synthesized anthocyanin can be converted into anthocyanidin or epicatechin. In red spines, the upregulation of BZ1 gene expression increases the corresponding anthocyanidin content, and the upregulation of the ANR gene also promotes the conversion of anthocyanin to epicatechin. The transcription factors involved in color formation included 4 WRKYs.

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中国红板栗脊柱颜色形成的代谢和分子机制

中国红板栗的刺是红色的，随着成熟度的增加，颜色的深度也逐渐加深。为了确定红板栗花青素的种类和合成途径，并找出调控花青素生物合成途径的关键基因，我们获得并分析了红板栗及其绿刺对照品种在 3 个不同时期的转录组和花青素代谢情况。GO 和 KEGG 分析表明，与红刺相比，光合作用在绿刺中的富集程度更高，而与防御和代谢调节相关的过程在红刺中的富集程度更高。分析表明，刺的颜色变化促进了红栗的光保护，尤其是在生长初期，这导致了参与防御代谢途径的差异表达基因的积累。代谢组结果显示，红刺中含有 6 种花青素。此外，红刺还表现出较高水平的青花素、芍药苷和芍药苷，以及较低水平的脱氢花青素、矮牵牛花青素和麦饭石花青素。与对照组相比，红刺中氰苷、芍药苷、芍药苷和麦冬苷的含量显著增加，表明红刺中氰苷和芍药苷途径在花青素的合成过程中含量丰富，而鹅掌楸苷途径则受到抑制，大部分转化为麦冬苷。在花色素合成过程中，CHS、CHI、F3H、CYP75A、CYP75B1、DFR和ANS基因的表达量明显增加，CYP73A基因的表达量明显减少，PAL、4CL和LAR基因的表达量有增有减。值得注意的是，研究结果表明，合成的花青素可转化为花色素或表儿茶素。在红刺中，BZ1基因表达的上调增加了相应的花青素含量，ANR基因的上调也促进了花青素向表儿茶素的转化。参与颜色形成的转录因子包括 4 个 WRKY。

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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Frontiers in Plant Science

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