免疫信号轴揭示水稻与病原菌斗争的秘密

doi:10.11983/CBB21160

植物学报 ›› 2021, Vol. 56 ›› Issue (5): 513-515.DOI: 10.11983/CBB21160 cstr: 32102.14.CBB21160

• 热点评述 • 下一篇

免疫信号轴揭示水稻与病原菌斗争的秘密

周俭民()

中国科学院遗传与发育生物学研究所植物基因组学国家重点实验室, 北京 100101

收稿日期:2021-09-14 接受日期:2021-09-17 出版日期:2021-09-01 发布日期:2021-09-30
通讯作者: 周俭民
作者简介:* E-mail: jmzhou@genetics.ac.cn
基金资助:
国家重点研发计划(2016YFD0100601)

A Ca²⁺-ROS Signaling Axis in Rice Provides Clues to Rice-pathogen Coevolution and Crop Improvements

Jian-Min Zhou()

State Key Laboratory of Plant Genomics, Institute of Genetics and Developmental Biology, Chinese Academy of Sciences, Beijing 100101, China

Received:2021-09-14 Accepted:2021-09-17 Online:2021-09-01 Published:2021-09-30
Contact: Jian-Min Zhou

摘要/Abstract

摘要： 近年, 我国学者在水稻(Oryza sativa)广谱抗病机制、抗性与产量协调机制等方向的研究取得了一系列突破性进展。最近, 何祖华和杨卫兵团队在水稻抗病性研究中再次取得突破, 发现1个以钙感应蛋白ROD1和过氧化氢酶CatB为核心的信号轴, 通过负调控水稻免疫反应, 保证正常生长条件下维持低水平的免疫反应, 促进水稻正常生长发育, 而在病原菌侵染时下调ROD1蛋白, 诱导免疫反应。ROD1缺失突变体高抗稻瘟病、纹枯病和白叶枯病, 但因免疫过强抑制生殖生长。需要指出的是, 在热带和亚热带栽培籼稻中, ROD1富集了1个独特的变异SNP1^A。SNP1^A对免疫的抑制作用较小, 因此具有较好的抗病性, 这可能对水稻在热带和亚热带的适应性具有重要意义。SNP1^A对水稻生长发育和产量无明显影响, 表明这一变异在抗病改良育种中可能具有重要价值。有意思的是, 某些稻瘟菌携带的效应蛋白AvrPiz-t, 通过模拟ROD1的结构和功能干扰水稻的抗病性。因此, ROD1-CatB信号轴在水稻与病原微生物适应性演化中具有独特意义。

关键词: 水稻, 抗病, 产量, 植物免疫, 效应蛋白

Abstract: Chinese scientists have made multiple breakthroughs in recent years in rice disease resistance studies, particularly in the areas of durable resistance and resistance-yield coordination. Most recently, a team led by Zuhua He and Weibing Yang at the CAS Center for Excellence in Molecular Plant Sciences made another major advance in our understanding of disease resistance and host-pathogen co-evolution in rice. They showed that the calcium sensor protein ROD1 directly enhances the activity of catalase protein CatB to remove reactive oxygen species during immune responses, preventing excessive immune responses and ensuring optimum rice plant growth. Remarkably, they also illustrated that a functionally attenuated variant of ROD1 is enriched in wild and domesticated Indica rice from tropical and subtropical regions and that this variant allows elevated resistance against sheath blight disease. Importantly, this variant is likely useful for breeding as it does not compromise rice growth and yield. Interestingly, they further demonstrated that an effector protein from the rice blast fungus structurally and functionally mimics ROD1 to suppress rice immunity. Thus, this study uncovers an immune regulatory axis defined by ROD1 and CatB that is at the center of rice-pathogen co-evolution.

Key words: rice, disease resistance, yield, plant immunity, effectors

周俭民. 免疫信号轴揭示水稻与病原菌斗争的秘密. 植物学报, 2021, 56(5): 513-515.

Jian-Min Zhou. A Ca²⁺-ROS Signaling Axis in Rice Provides Clues to Rice-pathogen Coevolution and Crop Improvements. Chinese Bulletin of Botany, 2021, 56(5): 513-515.

导出引用管理器 EndNote|Ris|BibTeX

链接本文: https://www.chinbullbotany.com/CN/10.11983/CBB21160

https://www.chinbullbotany.com/CN/Y2021/V56/I5/513

图/表 1

参考文献 11

[1]	Bai SW, Liu J, Chang C, Zhang L, Maekawa T, Wang QY, Xiao WK, Liu YL, Chai JJ, Takken FLW, Schulze-Lefert P, Shen QH (2012). Structure-function analysis of barley NLR immune receptor MLA10 reveals its cell compartment specific activity in cell death and disease resistance. PLoS Pathog 8, e1002752. DOI URL
[2]	Bi GZ, Su M, Li N, Liang Y, Dang S, Xu JC, Hu MJ, Wang JZ, Zou MX, Deng YN, Li QY, Huang SJ, Li JJ, Chai JJ, He KM, Chen YH, Zhou JM (2021). The ZAR1 resistosome is a calcium-permeable channel triggering plant immune signaling. Cell 184, 3528-3541. DOI URL
[3]	Bonman JM, Khush GS, Nelson RJ (1992). Breeding rice for resistance to pests. Annu Rev Phytopathol 30, 507-528. DOI URL
[4]	Deng YW, Zhai KR, Xie Z, Yang DY, Zhu XD, Liu JZ, Wang X, Qin P, Yang YZ, Zhang GM, Li Q, Zhang JF, Wu SQ, Milazzo J, Mao BZ, Wang ET, Xie HA, Tharreau D, He ZH (2017). Epigenetic regulation of antagonistic receptors confers rice blast resistance with yield balance. Science 355, 962-965. DOI URL
[5]	Gao M, He Y, Yin X, Zhong X, Yan B, Wu Y, Chen J, Li X, Zhai K, Huang Y, Gong X, Chang H, Xie S, Liu J, Yue J, Xu J, Zhang G, Deng Y, Wang E, Tharreau D, Wang GL, Yang W, He Z (2021). Ca²⁺ sensor-mediated ROS scavenging suppresses rice immunity and is exploited by a fungal effector. Cell 184, 5391-5404. DOI URL
[6]	Kadota Y, Sklenar J, Derbyshire P, Stransfeld L, Asai S, Ntoukakis V, Jones JDG, Shirasu K, Menke F, Jones A, Zipfel C (2014). Direct regulation of the NADPH oxidase RBOHD by the PRR-associated kinase BIK1 during plant immunity. Mol Cell 54, 43-55. DOI URL
[7]	Li L, Li M, Yu LP, Zhou ZY, Liang XX, Liu ZX, Cai GH, Gao LY, Zhang XJ, Wang YC, Chen S, Zhou JM (2014). The FLS2-associated kinase BIK1 directly phosphorylates the NADPH oxidase RBOHD to control plant immunity. Cell Host Microbe 15, 329-338. DOI URL
[8]	Li WT, Zhu ZW, Chern M, Yin JJ, Yang C, Ran L, Cheng MP, He M, Wang K, Wang J, Zhou XG, Zhu XB, Chen ZX, Wang JC, Zhao W, Ma BT, Qin P, Chen WL, Wang YP, Liu JL, Wang WM, Wu XJ, Li P, Wang JR, Zhu LH, Li SG, Chen XW (2017). A natural allele of a transcription factor in rice confers broad-spectrum blast resistance. Cell 170, 114-126. DOI URL
[9]	Park CH, Chen SB, Shirsekar G, Zhou B, Khang CH, Songkumarn P, Afzal AJ, Ning YS, Wang RY, Bellizzi M, Valent B, Wang GL (2012). The Magnaporthe oryzae effector AvrPiz-t targets the RING E3 Ubiquitin Ligase APIP6 to suppress pathogen-associated molecular pat-tern-triggered immunity in rice. Plant Cell 24, 4748-4762. DOI URL
[10]	Wang J, Zhou L, Shi H, Chern M, Yu H, Yi H, He M, Yin JJ, Zhu XB, Li Y, Li WT, Liu JL, Wang JC, Chen XQ, Qing H, Wang YP, Liu GF, Wang WM, Li P, Wu XJ, Zhu LH, Zhou JM, Ronald PC, Li SG, Li JY, Chen XW (2018). A single transcription factor promotes both yield and immunity in rice. Science 361, 1026-1028. DOI URL
[11]	Yuan HM, Liu WC, Lu YT (2017). CATALASE2 coordinates SA-mediated repression of both auxin accumulation and JA biosynthesis in plant defenses. Cell Host Microbe 21, 143-155. DOI URL

[1]	阳锦华, 王冰. 独脚金内酯受体精准改造助力水稻抗病毒“防卫战”[J]. 植物学报, 2026, 61(3): 357-368.
[2]	张月璇, 王鹏. 丛枝菌根真菌效应蛋白研究进展[J]. 植物学报, 2026, 61(3): 519-528.
[3]	李月琪, 麻仲花, 刘威帆, 苏明, 万猛虎, 李清云, 张丹, 刘吉利, 吴娜. 垂直深旋耕配施有机肥对盐碱地玉米叶片衰老特性及产量的影响[J]. 植物生态学报, 2026, 50(1): 222-236.
[4]	徐恩相, 周蕾, 章晓炜, 张国萍, 仲杜伟, 黄智, 刘派, 迟永刚. 基于不同生育阶段冠层光谱和碳通量的水稻产量估算[J]. 植物生态学报, 2026, 50(1): 82-93.
[5]	王志波, 刘文胜, 吴瑞俊, 王国梁. 2018-2023年黄土高原丘陵沟壑区川台地农田长期监测样地作物收获期性状和产量数据集[J]. 植物生态学报, 2025, 49(8): 1301-1311.
[6]	王书伟, 林静慧, 周伟, 单军, 赵旭, 颜晓元. 2004-2020年太湖平原典型农田生态系统长期监测样地作物收获期性状和产量数据集[J]. 植物生态学报, 2025, 49(8): 1283-1292.
[7]	王鹏, 李向义, 高艳菊, 热甫开提·沙比提, 曾凡江. 2005-2010年塔克拉玛干沙漠南缘绿洲农田长期监测样地棉花收获期性状和产量数据集[J]. 植物生态学报, 2025, 49(8): 1329-1338.
[8]	朱喜, 何志斌, 杜明武, 赵丽雯, 吴丹丹. 2004-2010年河西走廊中段绿洲农田生态系统长期监测样地作物性状和产量数据集[J]. 植物生态学报, 2025, 49(8): 1312-1320.
[9]	樊月玲, 蒋正德, 叶佳舒, 郑立臣, 陈欣. 2005-2015年下辽河平原农田长期观测样地主要农作物收获期性状和产量数据集[J]. 植物生态学报, 2025, 49(8): 1271-1282.
[10]	李少伟, 何永涛, 孙维, 戴尔阜. 2016-2020年拉萨河谷典型农田生态系统长期监测样地作物收获期性状和产量数据集[J]. 植物生态学报, 2025, 49(8): 1321-1328.
[11]	张斌, 张浩成, 乔天, 吕治兵, 许亚男, 李雪芹, 原向阳, 冯美臣, 张美俊. 接种丛枝菌根真菌对干旱胁迫燕麦非结构性碳水化合物及碳氮磷化学计量特征的影响[J]. 植物生态学报, 2025, 49(7): 1082-1095.
[12]	严文秀, 赵诗晗, 郑春燕, 张萍, 沈海花, 常锦峰, 徐亢. 基于多物候指标的人工饲草长势监测及产量估测[J]. 植物生态学报, 2025, 49(7): 1096-1109.
[13]	郭宇荣, 刘红, 王振华, 田岗, 刘鑫, 郭杰, 李春勇, 李会霞. 长杂谷系列谷子杂交种产量优势及其生理机制[J]. 植物学报, 2025, 60(6): 931-943.
[14]	吴玉俊, 李英菊, 罗巧玉, 马永贵. 光控植物免疫: 从光信号通路到免疫应答的调控网络[J]. 植物学报, 2025, 60(5): 786-803.
[15]	史世肸, 严顺平. 高效液相色谱法检测水杨酸的优化[J]. 植物学报, 2025, 60(5): 846-853.

免疫信号轴揭示水稻与病原菌斗争的秘密

A Ca²⁺-ROS Signaling Axis in Rice Provides Clues to Rice-pathogen Coevolution and Crop Improvements

RichHTML

PDF (PC)

可视化

被引次数

摘要/Abstract

引用本文

使用本文

图/表 1

参考文献 11

相关文章 15

编辑推荐

Metrics

本文评价

免疫信号轴揭示水稻与病原菌斗争的秘密

A Ca2+-ROS Signaling Axis in Rice Provides Clues to Rice-pathogen Coevolution and Crop Improvements

RichHTML

PDF (PC)

可视化

被引次数

摘要/Abstract

引用本文

使用本文

图/表 1

参考文献 11

相关文章 15

编辑推荐

Metrics

本文评价

A Ca²⁺-ROS Signaling Axis in Rice Provides Clues to Rice-pathogen Coevolution and Crop Improvements