Diverse O-methyltransferases catalyze the biosynthesis of floral benzenoids that repel aphids from the flowers of waterlily Nymphaea prolifera.

IF 7.6 Q1 GENETICS & HEREDITY 园艺研究(英文) Pub Date : 2023-11-06 eCollection Date: 2023-12-01 DOI:10.1093/hr/uhad237
Guanhua Liu, Jianyu Fu, Lingyun Wang, Mingya Fang, Wanbo Zhang, Mei Yang, Xuemin Yang, Yingchun Xu, Lin Shi, Xiaoying Ma, Qian Wang, Hui Chen, Cuiwei Yu, Dongbei Yu, Feng Chen, Yifan Jiang
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Abstract

Nymphaea is a key genus of the ANA grade (Amborellales, Nymphaeales, and Austrobaileyales) of basal flowering plants, which serve as a key model to study the early evolution of floral traits. In this study, we comprehensively investigated the emission, biosynthesis, and biological function of the floral scent in a night-blossoming waterlily Nymphaea prolifera. The headspace volatile collection combined with GC-MS analysis showed that the floral scent of N. prolifera is predominately comprised by methylated benzenoids including anisole, veratrole, guaiacol, and methoxyanisole. Moreover, the emission of these floral benzenoids in N. prolifera exhibited temporal and spatial pattern with circadian rhythm and tissue specificity. By creating and mining transcriptomes of N. prolifera flowers, 12 oxygen methyltransferases (NpOMTs) were functionally identified. By in vitro enzymatic assay, NpOMT3, 6, and 7 could produce anisole and NpOMT5, 7, 9, produce guaiacol, whereas NpOMT3, 6, 9, 11 catalyzed the formation of veratrole. Methoxyanisole was identified as the universal product of all NpOMTs. Expression patterns of NpOMTs provided implication for their roles in the production of the respective benzenoids. Phylogenetic analysis of OMTs suggested a Nymphaea-specific expansion of the OMT family, indicating the evolution of lineage-specific functions. In bioassays, anisole, veratrole, and guaiacol in the floral benzenoids were revealed to play the critical role in repelling waterlily aphids. Overall, this study indicates that the basal flowering plant N. prolifera has evolved a diversity and complexity of OMT genes for the biosynthesis of methylated benzenoids that can repel insects from feeding the flowers. These findings provide new insights into the evolutional mechanism and ecological significance of the floral scent from early-diverged flowering plants.

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多种 O-甲基转移酶催化了能驱赶睡莲 Nymphaea prolifera 花中蚜虫的花苯类化合物的生物合成。
睡莲(Nymphaea)是基生开花植物 ANA 级(Amborellales, Nymphaeales, and Austrobaileyales)的一个重要属,是研究花性状早期进化的一个重要模型。本研究全面考察了夜开睡莲 Nymphaea prolifera 花香的散发、生物合成和生物功能。顶空挥发物收集和气相色谱-质谱分析表明,N. prolifera 的花香主要由甲基化苯类化合物组成,包括苯甲醚、藜芦、愈创木酚和甲氧基苯甲醚。此外,N. prolifera 中这些花香类苯甲醚的释放具有时空模式、昼夜节律和组织特异性。通过创建和挖掘N. prolifera花的转录组,确定了12个氧甲氧基转移酶(NpOMTs)的功能。通过体外酶促实验,NpOMT3、6 和 7 能产生苯甲醚,NpOMT5、7、9 能产生愈创木酚,而 NpOMT3、6、9、11 能催化形成 veratrole。甲氧基苯甲醚被确定为所有 NpOMTs 的通用产物。NpOMTs 的表达模式暗示了它们在生产相应苯并类化合物中的作用。对 OMTs 的系统进化分析表明,OMT 家族的扩展具有蛱蝶的特异性,这表明了其特定品系功能的进化。在生物测定中,发现花苯甲酮中的苯甲醚、维拉樟脑和愈创木酚在驱避睡莲蚜虫方面发挥了关键作用。总之,这项研究表明,基生开花植物 N. prolifera 进化出了多种复杂的 OMT 基因,用于生物合成甲基化类苯酮,从而驱赶昆虫取食花朵。这些发现为早期分化的有花植物花香的进化机制和生态学意义提供了新的见解。
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