Progressive meristem and single-cell transcriptomes reveal the regulatory mechanisms underlying maize inflorescence development and sex differentiation.

IF 17.1 1区 生物学 Q1 BIOCHEMISTRY & MOLECULAR BIOLOGY Molecular Plant Pub Date : 2024-07-01 Epub Date: 2024-06-13 DOI:10.1016/j.molp.2024.06.007
Yonghao Sun, Liang Dong, Lu Kang, Wanshun Zhong, David Jackson, Fang Yang
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Abstract

Maize develops separate ear and tassel inflorescences with initially similar morphology but ultimately different architecture and sexuality. The detailed regulatory mechanisms underlying these changes still remain largely unclear. In this study, through analyzing the time-course meristem transcriptomes and floret single-cell transcriptomes of ear and tassel, we revealed the regulatory dynamics and pathways underlying inflorescence development and sex differentiation. We identified 16 diverse gene clusters with differential spatiotemporal expression patterns and revealed biased regulation of redox, programmed cell death, and hormone signals during meristem differentiation between ear and tassel. Notably, based on their dynamic expression patterns, we revealed the roles of two RNA-binding proteins in regulating inflorescence meristem activity and axillary meristem formation. Moreover, using the transcriptional profiles of 53 910 single cells, we uncovered the cellular heterogeneity between ear and tassel florets. We found that multiple signals associated with either enhanced cell death or reduced growth are responsible for tassel pistil suppression, while part of the gibberellic acid signal may act non-cell-autonomously to regulate ear stamen arrest during sex differentiation. We further showed that the pistil-protection gene SILKLESS 1 (SK1) functions antagonistically to the known pistil-suppression genes through regulating common molecular pathways, and constructed a regulatory network for pistil-fate determination. Collectively, our study provides a deep understanding of the regulatory mechanisms underlying inflorescence development and sex differentiation in maize, laying the foundation for identifying new regulators and pathways for maize hybrid breeding and improvement.

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渐进分生组织和单细胞转录组揭示了玉米花序发育和性别分化的调控机制。
玉米的穗花序和抽穗花序最初形态相似,但最后结构和性状却不同。这些变化背后的详细调控机制在很大程度上仍不清楚。本研究通过分析穗和缨的分生组织转录组和小花单细胞转录组,揭示了花序发育和性别分化的调控动态和途径。我们发现了16个具有不同时空表达模式的基因簇,并揭示了氧化还原、程序性细胞死亡和激素信号对穗和缨之间分生组织分化的偏向调控。特别是,根据它们的动态模式,我们揭示了两种 RNA 结合蛋白在调控花序分生组织活性和腋生分生组织形成中的作用。此外,利用 53,910 个单细胞的转录图谱,我们发现了穗小花和缨小花之间的细胞异质性。我们发现,与细胞死亡增强或生长减弱相关的多种信号是造成穗状花序雌蕊抑制的原因,而部分 GA 信号可能在性分化过程中以非细胞自主的方式调节穗状花序雄蕊的停滞。我们进一步发现,雌蕊保护基因SILKLESS 1(SK1)通过调控共同的分子通路与已知的雌蕊抑制基因起拮抗作用,并构建了雌蕊命运决定的调控模型。总之,我们的研究加深了对玉米花序发育和性别分化调控机制的理解,为确定玉米杂交育种和改良的新调控因子和途径奠定了基础。
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来源期刊
Molecular Plant
Molecular Plant 植物科学-生化与分子生物学
CiteScore
37.60
自引率
2.20%
发文量
1784
审稿时长
1 months
期刊介绍: Molecular Plant is dedicated to serving the plant science community by publishing novel and exciting findings with high significance in plant biology. The journal focuses broadly on cellular biology, physiology, biochemistry, molecular biology, genetics, development, plant-microbe interaction, genomics, bioinformatics, and molecular evolution. Molecular Plant publishes original research articles, reviews, Correspondence, and Spotlights on the most important developments in plant biology.
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