Yanshen Ren, Shuangyu Zhang, Qianyi Zhao, Yang Wu, Houhua Li
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引用次数: 0
Abstract
Drought stress has been demonstrated to enhance the biosynthesis of anthocyanins in the leaves, resulting in an increased aesthetic appeal. However, the molecular mechanisms underlying drought-induced anthocyanin biosynthesis in Chaenomeles speciosa remain unclear. In this study, the metabolites of C. speciosa leaves were analyzed, and it was found that the content of cyanidin-3-O-rutinoside increased significantly under drought stress. The differentially expressed genes CsMYB123 and CsbHLH111 were isolated by transcriptomics data analysis and gene cloning, and gene overexpression and VIGS experiments verified that both play important roles in anthocyanin biosynthesis. Subsequently, Y1H and Dual-luciferase reporter assay showed that CsMYB123 binds to the promoters of anthocyanin biosynthesis-related structural genes (such as CsCHI, CsF3H, and CsANS), while CsbHLH111 was shown to bind to the promoter of CsCHI, positively regulating its activity. Furthermore, BIFC and Y2H assays unveiled potential protein-protein interactions between CsMYB123 and CsbHLH111 at the cell nucleus. Collectively, these results shed light on the critical roles played by CsMYB123 and CsbHLH111 in anthocyanin biosynthesis, thus providing a valuable insight into understanding the molecular mechanisms of how the MYB and bHLH genes regulate anthocyanin biosynthesis in the process of leaf coloration in C. speciosa.
干旱胁迫已被证明可以增强叶片中花青素的生物合成,从而增加美学吸引力。然而,干旱诱导木瓜花青素生物合成的分子机制尚不清楚。本研究对金针桃叶片代谢产物进行了分析,发现干旱胁迫下花青素-3- o -芦丁苷含量显著升高。通过转录组学数据分析和基因克隆分离得到差异表达基因CsMYB123和csmylh111,基因过表达和VIGS实验验证了这两个基因在花青素生物合成中发挥重要作用。随后,通过Y1H和双荧光素酶报告基因检测发现,CsMYB123与花青素生物合成相关结构基因(如CsCHI、CsF3H和CsANS)的启动子结合,而csmylh111则与CsCHI的启动子结合,正调控其活性。此外,BIFC和Y2H检测揭示了CsMYB123和csmylh111在细胞核中潜在的蛋白-蛋白相互作用。综上所述,这些结果揭示了CsMYB123和csmylh111在花青素生物合成中的关键作用,从而为理解MYB和bHLH基因在金盏花叶片着色过程中调控花青素生物合成的分子机制提供了有价值的见解。
期刊介绍:
Aims
Molecular Horticulture aims to publish research and review articles that significantly advance our knowledge in understanding how the horticultural crops or their parts operate mechanistically. Articles should have profound impacts not only in terms of high citation number or the like, but more importantly on the direction of the horticultural research field.
Scope
Molecular Horticulture publishes original Research Articles, Letters, and Reviews on novel discoveries on the following, but not limited to, aspects of horticultural plants (including medicinal plants):
▪ Developmental and evolutionary biology
▪ Physiology, biochemistry and cell biology
▪ Plant-microbe and plant-environment interactions
▪ Genetics and epigenetics
▪ Molecular breeding and biotechnology
▪ Secondary metabolism and synthetic biology
▪ Multi-omics dealing with data sets of genome, transcriptome, proteome, metabolome, epigenome and/or microbiome.
The journal also welcomes research articles using model plants that reveal mechanisms and/or principles readily applicable to horticultural plants, translational research articles involving application of basic knowledge (including those of model plants) to the horticultural crops, novel Methods and Resources of broad interest.
In addition, the journal publishes Editorial, News and View, and Commentary and Perspective on current, significant events and topics in global horticultural fields with international interests.