Ontogeny and organ-specific steroidal glycoside diversity is associated with differential expression of steroidal glycoside pathway genes in two Solanum dulcamara leaf chemotypes.

IF 4.2 3区生物学 Q1 PLANT SCIENCES

Plant Biology Pub Date : 2024-08-16 DOI:10.1111/plb.13704

R A Anaia, I Chiocchio, R Sontowski, B Swinkels, F Vergara, N M van Dam

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引用次数: 0

Abstract

Solanaceous plants, such as Solanum dulcamara, produce steroidal glycosides (SGs). Leaf SG profiles vary among S. dulcamara individuals, leading to distinct phytochemical phenotypes ('chemotypes') and intraspecific phytochemical diversity ('chemodiversity'). However, if and how SG chemodiversity varies among organs and across ontogeny, and how this relates to SG metabolism gene expression is unknown. Among organs and across ontogeny, S. dulcamara plants with saturated (S) and unsaturated (U) SG leaf chemotypes were selected and clonally propagated. Roots, stems and leaves were harvested from vegetative and flowering plants. Extracts were analysed using untargeted LC-MS. Expression of candidate genes in SG metabolism (SdGAME9, SdGAME4, SdGAME25, SdS5αR2 and SdDPS) was analysed using RT-qPCRs. Our analyses showed that SG chemodiversity varies among organs and across ontogeny in S. dulcamara; SG richness (D_mg) was higher in flowering than vegetative plants. In vegetative plants, D_mg was higher for leaves than for roots. Lack of SdGAME25 expression in U-chemotype leaves, while readily expressed in roots and stems, suggests a pivotal role for SdGAME25 in differentiation of leaf chemotypes in vegetative and flowering plants. By acting as an ontogeny-dependent chemotypic switch, differential regulation of SdGAME25 enables adaptive allocation of SGs, thereby increasing SG chemodiversity in leaves. This indicates that differential expression and/or regulation of glycoalkaloid metabolism genes, rather than their presence or absence, explains observed chemotypic variation in SG chemodiversity among organs and across ontogeny.

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本体和器官特异性甾体苷多样性与两种茄科植物叶片化学型中甾体苷途径基因的不同表达有关。

茄科植物（如多香果茄）会产生甾醇苷（SGs）。S. dulcamara个体之间的叶片 SG 特征各不相同，从而产生了不同的植物化学表型（"化学型"）和种内植物化学多样性（"化学多样性"）。然而，植物生长素的化学多样性在不同器官和不同个体发育过程中是否会发生变化、如何变化，以及这种变化与植物生长素代谢基因表达的关系如何，目前尚不清楚。在不同器官和不同发育阶段，选择了具有饱和（S）和不饱和（U）SG 叶片化学型的杜仲植株，并进行了克隆繁殖。从无性繁殖植株和开花植株上采集根、茎和叶。使用非靶向 LC-MS 对提取物进行分析。使用 RT-qPCR 分析了 SG 代谢候选基因（SdGAME9、SdGAME4、SdGAME25、SdS5αR2 和 SdDPS）的表达。我们的分析表明，在杜鹃花中，不同器官和不同生长期的 SG 化学多样性各不相同；开花植株的 SG 丰富度（Dmg）高于无性系植株。在无性系植株中，叶片的 Dmg 高于根。SdGAME25 在 U 化学型叶片中缺乏表达，而在根和茎中很容易表达，这表明 SdGAME25 在无性繁殖植物和开花植物叶片化学型的分化中起着关键作用。SdGAME25 作为一种依赖于本体的化学型开关，其不同的调控方式可实现 SG 的适应性分配，从而增加叶片中 SG 的化学多样性。这表明，糖类生物碱代谢基因的不同表达和/或调控，而不是其存在或不存在，解释了所观察到的器官间和本体发育过程中SG化学多样性的化学型差异。

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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来源期刊

Plant Biology 生物-植物科学

CiteScore

8.20

自引率

2.60%

发文量

109

审稿时长

3 months

期刊介绍： Plant Biology is an international journal of broad scope bringing together the different subdisciplines, such as physiology, molecular biology, cell biology, development, genetics, systematics, ecology, evolution, ecophysiology, plant-microbe interactions, and mycology. Plant Biology publishes original problem-oriented full-length research papers, short research papers, and review articles. Discussion of hot topics and provocative opinion articles are published under the heading Acute Views. From a multidisciplinary perspective, Plant Biology will provide a platform for publication, information and debate, encompassing all areas which fall within the scope of plant science.