Physiological characteristics and gene regulation mechanism of juvenile leaves of Acer rubrum L. during leaf color transformation in spring

Han, Xuan; Ge, Wei; Wang, Zhikun; Cui, Jinteng; Zhang, Kezhong

doi:10.1163/22238980-bja10056

Cited by 1 publication

(1 citation statement)

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“…Therefore, we speculate that ABA-mediated chlorophyll degradation may also participate in the regulation of leaf color change of ‘Ziyan Gongzhu’. In previous studies, ethylene signal pathway inhibits carotenoid synthesis and ABA signal pathway promotes anthocyanin synthesis [ 79 ], but no related regulatory factors have been found in this study, The specific mechanism of hormones involved in regulating leaf color change of color-leafed plants needs further study.…”

Section: Discussionmentioning

confidence: 61%

Mechanisms for leaf color changes in Osmanthus fragrans ‘Ziyan Gongzhu’ using physiology, transcriptomics and metabolomics

Guo,

Huang,

Zhao

et al. 2023

BMC Plant Biol

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Background Color-leaved O. fragrans is a variety of Osmanthus fragrans, which has both the fragrance of Osmanthus and the color of color-leaved plants. However, the molecular mechanism of color change of color-leaved O. fragrans is not clear. In this study, we analyzed the regulatory mechanism of four different color leaves of ‘Ziyan Gongzhu’ through physiological, transcriptome and metabolome levels. Results Firstly, we measured the leaf pigments content and leaf chromatic parameters for correlation analysis, indicating a significant correlation between them. Overall, the content of chlorophyll a + b is low and the content of anthocyanin is high in T1 and T2 leaves, along with low expression of chlorophyll synthesis genes (HEMA, CHLG, and CAO, etc.) and high expression of anthocyanin synthesis genes (F3H, F3’H, DFR and ANS, etc.), resulting purple red and light purple in T1 and T2 leaves, respectively. It was also found that the pigment closely related to the color leaves of ‘Ziyan Gongzhu’ was cyanidin. The content anthocyanins, may be regulated by two putative MYB activators (OfMYB3 and OfMYB4) and two putative MYB repressors (OfMYB1 and OfMYB2). In contrast, the content of chlorophyll a + b is high and the content of anthocyanin is low in T3 and T4 leaves, along with high expression of chlorophyll synthesis genes and low expression of anthocyanin synthesis genes, resulting yellow green and dark green in T3 and T4 leaves, respectively. And abnormal chloroplast development affects chlorophyll content in T1, T2, and T3 leaves. Although the content of carotenoids first dropped in T2 leaves, it then rapidly accumulated in T4 leaves, in sync with the increase in the expression of genes related to carotenoid biosynthesis (ZDS, LHYB, and ZEP, for example). Analysis of photosynthetic, carbohydrate and hormone-related differentially abundant metabolites (DAMs) and DEGs found that they may participate in the regulation of leaf color change of ‘Ziyan Gongzhu’ by affecting pigment synthesis. Conclusion Our results pave the way for a comprehensive knowledge of the regulatory processes governing leaf color in ‘Ziyan Gongzhu’ and identify possible genes for application regarding molecular colored-leaf cultivar breeding.

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Section: Discussionmentioning

confidence: 61%