Doosan Shin, Haohao Zhao, Ethan Tucker, Keun Ho Cho, Dake Liu, Zhixin Wang, Scott Latimer, Gilles Basset, Yu Wang, Yousong Ding, Jeongim Kim
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引用次数: 0
Abstract
Flavonols are subclasses of flavonoids, with hundreds of structures identified in plants. This chemical diversity primarily arises from glycosylation, where sugars are selectively added to the flavonol backbone. While flavonol profiles vary across species and organs, the evolutionary forces shaping this chemodiversity and the physiological significance of specific glycosides remain a mystery. Here, we reveal that finely tuned transcriptional regulation and the sugar selectivity of glycosyltransferases drive the formation of distinct organ specific flavonol profiles and a specific flavonol is necessary for male fertility. In Solanaceae pollen, two flavonol glycosides, K2 (kaempferol 3- O -glucosyl(1 → 2)galactoside) and Q2 (quercetin 3- O -glucosyl(1 → 2)galactoside), are exclusively accumulated. K2 is evolutionarily conserved, while Q2 was lost over time. Consistently, K2 is essential for male fertility, whereas Q2 and aglycones fail to rescue fertility defects. These findings suggest that individual flavonol glycosides have distinct physiological roles, either actively maintained or discarded through evolutionary selection.
黄酮醇是黄酮类化合物的亚类,在植物中有数百种结构。这种化学多样性主要来自糖基化,其中糖被选择性地添加到黄酮醇骨架上。虽然不同物种和器官的黄酮醇谱不同,但形成这种化学多样性的进化力量和特定糖苷的生理意义仍然是一个谜。在这里,我们揭示了精细调节的转录调控和糖基转移酶的糖选择性驱动了不同器官特异性黄酮醇谱的形成,而特定的黄酮醇是男性生育所必需的。在茄科花粉中,两种黄酮醇苷,K2(山奈酚3- O -葡萄糖基(1→2)半乳糖苷)和Q2(槲皮素3- O -葡萄糖基(1→2)半乳糖苷)是专门积累的。K2在进化上是保守的,而Q2则随着时间的推移而丢失。一直以来,K2对男性生育能力至关重要,而Q2和苷元不能挽救生育缺陷。这些发现表明,个体黄酮醇苷具有不同的生理作用,要么通过进化选择积极维持,要么被抛弃。
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