单细胞转录组分析揭示了藜盐膀胱的发育轨迹和转录调控网络。

Hao Liu, Zhixin Liu, Yaping Zhou, Aizhi Qin, Chunyang Li, Yumeng Liu, Peibo Gao, Qianli Zhao, Xiao Song, Mengfan Li, Luyao Kong, Yajie Xie, Lulu Yan, Enzhi Guo, Xuwu Sun
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引用次数: 0

摘要

盐囊是藜麦叶片表面的特化结构,能分泌 Na+ 以减轻非生物胁迫(尤其是盐暴露)对植物的影响。了解这些结构的发展对于阐明藜麦的耐盐机制至关重要。在本研究中,我们利用透射电子显微镜详细研究了藜麦盐囊各发育阶段的细胞分化。为了进一步探索发育轨迹和潜在的分子机制,我们对来自幼叶的藜麦原生质体进行了单细胞 RNA 测序。这使我们能够构建细胞图谱,识别出 13 个不同的细胞群。通过假时分析,我们绘制了盐膀胱的发育途径图,并确定了参与细胞命运决定的调控因子。GO和KEGG富集分析以及实验结果揭示了盐胁迫以及硫和氮的剥夺对藜麦盐囊发育的影响。对茎前细胞(pre-SC)、茎细胞(SC)和表皮膀胱细胞(EBC)中转录因子相互作用网络的分析表明,TCP5、YAB5、NAC078、SCL8、GT-3B和T1P17.40在EBC的发育过程中起着至关重要的作用。基于我们的研究结果,我们建立了一个信息丰富的模型来阐明盐囊的形成。这项研究为绘制藜麦叶细胞图谱提供了重要资源,有助于我们了解藜麦的耐盐机制。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Single-cell transcriptomic analysis reveals the developmental trajectory and transcriptional regulatory networks of quinoa salt bladders.

Salt bladders, specialized structures on the surface of quinoa leaves, secrete Na+ to mitigate the effects of the plant from abiotic stresses, particularly salt exposure. Understanding the development of these structures is crucial for elucidating quinoa's salt tolerance mechanisms. In this study, we employed transmission electron microscopy to detail cellular differentiation across the developmental stages of quinoa salt bladders. To further explore the developmental trajectory and underlying molecular mechanisms, we conducted single-cell RNA sequencing on quinoa protoplasts derived from young leaves. This allowed us to construct a cellular atlas, identifying 13 distinct cell clusters. Through pseudotime analysis, we mapped the developmental pathways of salt bladders and identified regulatory factors involved in cell fate decisions. GO and KEGG enrichment analyses, as well as experimental results, revealed the impacts of salt stress and the deprivation of sulfur and nitrogen on the development of quinoa salt bladders. Analysis of the transcription factor interaction network in pre-stalk cells (pre-SC), stalk cells (SC), and epidermal bladder cells (EBCs) indicated that TCP5, YAB5, NAC078, SCL8, GT-3B, and T1P17.40 play crucial roles in EBC development. Based on our findings, we developed an informative model elucidating salt bladder formation. This study provides a vital resource for mapping quinoa leaf cells and contributes to our understanding of its salt tolerance mechanisms.

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