Transcriptomic landscape ofseedstickinArabidopsis thalianafuniculus after fertilisation

Maria João Ferreira, Jessy Silva, Hidenori Takeuchi, Takamasa Suzuki, Tetsuya Higashiyama, Sílvia Vieira de Almeida Coimbra
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Abstract

In Angiosperms, the continuation of plant species is intricately dependent on the funiculus multifaceted role in nutrient transport, mechanical support, and dehiscence of seeds. SEEDSTICK (STK) is a MADS-box transcription factor involved in seed size and dehiscence, and one of the few genes identified as affecting funiculus growth. Given the importance of the funiculus to a correct seed development, allied with previous phenotypic observations of stk mutants, we performed a transcriptomic analysis of stk funiculi, using RNA-sequencing, to infer on the deregulated networks of genes. The generated dataset of differentially expressed genes was enriched with cell wall biogenesis, cell cycle, sugar metabolism and transport terms, all in accordance with stk phenotype. We selected eight differentially expressed genes involved with abscission, seed development or novel functions in stk funiculus, such as hormones/secondary metabolites transport, for transcriptome validation using qPCR and/or promoter reporter lines. Overall, the analysis performed in this study allowed delving into the STK-network established in Arabidopsis funiculus, fulfilling a literature gap. Simultaneously, our findings reinforced the reliability of the transcriptome, and identified processes and new candidate genes that will enable a better understanding on the role of this sporophytic structure and how seed development may be affected by it.
拟南芥受精后种子粘附的转录组景观
在被子植物中,植物物种的延续复杂地依赖于球囊在营养转运、机械支持和种子开裂等方面的多重作用。SEEDSTICK (STK)是一种MADS-box转录因子,与种子大小和开裂有关,是为数不多的影响球茎生长的基因之一。考虑到索柄对正确的种子发育的重要性,结合之前对索柄突变体的表型观察,我们使用rna测序对索柄进行了转录组学分析,以推断基因的非调控网络。生成的差异表达基因数据集丰富了细胞壁生物发生、细胞周期、糖代谢和运输等术语,这些术语都与stk表型一致。我们选择了8个差异表达的基因,这些基因与茎的脱落、种子发育或新功能有关,如激素/次生代谢物运输,使用qPCR和/或启动子报告系进行转录组验证。总的来说,本研究的分析可以深入研究拟南芥中建立的stk -网络,填补了文献空白。同时,我们的发现加强了转录组的可靠性,并确定了过程和新的候选基因,这将使我们更好地了解这种孢子体结构的作用以及它如何影响种子发育。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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