转录因子WFZP与染色质重塑因子TaSYD相互作用，调控小麦根系结构和氮素吸收效率。

The Transcription Factor WFZP Interacts with the Chromatin Remodeler TaSYD to Regulate Root Architecture and Nitrogen Uptake Efficiency in Wheat.

作者信息

Du Dejie, Li Zhaoju, Jiang Zihao, Yuan Jun, Zhang Xiangyu, Zhao Huanhuan, Tian Lulu, Liu Yunjie, Li Renhan, He Fei, Li Xiongtao, Ke Wensheng, Chai Lingling, Liu Jie, Xin Mingming, Yao Yingyin, Sun Qixin, Xing Jiewen, Ni Zhongfu

机构信息

Frontiers Science Center for Molecular Design Breeding, Key Laboratory of Crop Heterosis and Utilization (MOE), Key Laboratory of Crop Genetic Improvement, China Agricultural University, Beijing, 100193, China.

出版信息

Adv Sci (Weinh). 2025 Apr;12(15):e2416433. doi: 10.1002/advs.202416433. Epub 2025 Feb 24.

DOI:10.1002/advs.202416433

PMID:39992804

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12005776/

Abstract

The root architecture is crucial for the robust growth and nutrient absorption in cereals. However, it is urgent to identify the factors that simultaneously optimize root architecture and nutrient utilization in wheat. In this study, a beneficial role of the class II AP2/ERF transcription factor WHEAT FRIZZY PANICLE (WFZP) on lateral root number (LRN), root length (RL), and nitrogen utilization is revealed. In addition, interactors of WFZP including TaSYD are identified, as a subunit of the chromatin remodeling complex. The Tasyd mutants show a significant reduction in LRN, RL, and nitrogen uptake efficiency, resembling the phenotype of wfzp mutants. Furthermore, it is revealed that the WFZP-TaSYD module promotes the expression of root development and nitrate uptake-related genes by modulating chromatin accessibility and histone modifications. Finally, an elite allele (WFZP-A-I) associated with improved LRN and thousand-grain weight (TGW) is identified. Hence, these findings not only unveil the mechanisms underlying the coordination of root development and nitrogen uptake efficiency, but also provide valuable targets for breeding high-yield crops.

摘要

根系结构对于谷类作物的稳健生长和养分吸收至关重要。然而，确定同时优化小麦根系结构和养分利用的因素迫在眉睫。在本研究中，揭示了II类AP2/ERF转录因子小麦卷曲穗（WFZP）对侧根数（LRN）、根长（RL）和氮利用的有益作用。此外，还鉴定了包括TaSYD在内的WFZP相互作用因子，TaSYD是染色质重塑复合体的一个亚基。Tasyd突变体的LRN、RL和氮吸收效率显著降低，类似于wfzp突变体的表型。此外，研究表明WFZP-TaSYD模块通过调节染色质可及性和组蛋白修饰来促进根系发育和硝酸盐吸收相关基因的表达。最后，鉴定出一个与LRN和千粒重（TGW）提高相关的优良等位基因（WFZP-A-I）。因此，这些发现不仅揭示了根系发育与氮吸收效率协调的机制，也为高产作物育种提供了有价值的靶点。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/1f8e/12005776/89f432a611c4/ADVS-12-2416433-g006.jpg

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转录因子WFZP与染色质重塑因子TaSYD相互作用，调控小麦根系结构和氮素吸收效率。

The Transcription Factor WFZP Interacts with the Chromatin Remodeler TaSYD to Regulate Root Architecture and Nitrogen Uptake Efficiency in Wheat.

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