Genome-wide analysis of cis-regulatory element structure and discovery of motif-driven gene co-expression networks in grapevine

D. Wong, R. Lopez Gutierrez, G. Gambetta, S. Castellarin
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引用次数: 30

Abstract

Abstract Coordinated transcriptional and metabolic reprogramming ensures a plant’s continued growth and survival under adverse environmental conditions. Transcription factors (TFs) act to modulate gene expression through complex cis-regulatory element (CRE) interactions. Genome-wide analysis of known plant CREs was performed for all currently predicted protein-coding gene promoters in grapevine (Vitis vinifera L.). Many CREs such as abscisic acid (ABA)-responsive, drought-responsive, auxin-responsive, and evening elements, exhibit bona fide CRE properties such as strong position bias towards the transcription start site (TSS) and over-representation when compared with random promoters. Genes containing these CREs are enriched in a large repertoire of plant biological pathways. Large-scale transcriptome analyses also show that these CREs are highly implicated in grapevine development and stress response. Numerous CRE-driven modules in condition-specific gene co-expression networks (GCNs) were identified and many of these modules were highly enriched for plant biological functions. Several modules corroborate known roles of CREs in drought response, pathogen defense, cell wall metabolism, and fruit ripening, whereas others reveal novel functions in plants. Comparisons with Arabidopsis suggest a general conservation in promoter architecture, gene expression dynamics, and GCN structure across species. Systems analyses of CREs provide insights into the grapevine cis-regulatory code and establish a foundation for future genomic studies in grapevine.
葡萄藤顺式调控元件结构的全基因组分析及基序驱动基因共表达网络的发现
协调的转录和代谢重编程确保了植物在不利环境条件下的持续生长和生存。转录因子(tf)通过复杂的顺式调控元件(CRE)相互作用来调节基因表达。对葡萄(Vitis vinifera L.)中所有目前预测的蛋白编码基因启动子进行了全基因组分析。许多CRE,如脱落酸(ABA)响应、干旱响应、生长素响应和夜间元件,与随机启动子相比,表现出真正的CRE特性,如对转录起始位点(TSS)的强烈位置偏倚和过度代表性。含有这些cre的基因丰富于大量的植物生物学途径中。大规模转录组分析也表明,这些cre与葡萄藤的发育和应激反应密切相关。在条件特异性基因共表达网络(GCNs)中发现了许多由cred驱动的模块,其中许多模块具有高度富集的植物生物学功能。一些模块证实了cre在干旱响应、病原体防御、细胞壁代谢和果实成熟中的已知作用,而其他模块则揭示了植物中的新功能。与拟南芥的比较表明,启动子结构、基因表达动态和GCN结构在物种间具有普遍的保守性。cre的系统分析提供了对葡萄藤顺式调控代码的见解,并为葡萄藤的未来基因组研究奠定了基础。
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