水稻茎秆强度遗传研究进展

doi:10.11924/j.issn.1000-6850.casb2025-0504

中国农学通报 ›› 2025, Vol. 41 ›› Issue (21): 36-42.doi: 10.11924/j.issn.1000-6850.casb2025-0504

• 生物育种前沿共性技术 • 上一篇下一篇

水稻茎秆强度遗传研究进展

常汇琳(), 高世伟, 刘晴, 刘宇强, 马成, 沙汉景, 王婧泽, 聂守军()

黑龙江省农业科学院绥化分院，黑龙江绥化 152000

收稿日期:2025-06-09 修回日期:2025-07-15 出版日期:2025-07-25 发布日期:2025-08-05
通讯作者:
聂守军，男，1969年出生，黑龙江绥化人，研究员，硕士，主要从事水稻育种与栽培研究。通信地址：152000 黑龙江省绥化市北林区工农西路420号，Tel：0455-8398545，E-mail：Nsj-0821@163.com。
作者简介:
常汇琳，女，1991年出生，黑龙江绥化人，助理研究员，博士，研究方向：水稻遗传育种。通信地址：152000 黑龙江省绥化市北林区工农西路420号，Tel：0455-8398542，E-mail：forestC0915@haas.cn。
基金资助:
黑龙江省农业科技创新跨越工程重大需求科技创新攻关项目“中晚熟优质高产广适水稻新品种选育推广与产业化开发”(CX23ZD02); 黑龙江省农业科学院绥化分院科技创新基础项目(B)类“寒地优质抗病水稻种质资源创制及应用”(SHFY2022-07)

Genetic Research Progress of Rice Culm Strength

CHANG Huilin(), GAO Shiwei, LIU Qing, LIU Yuqiang, MA Cheng, SHA Hanjing, WANG Jingze, NIE Shoujun()

Suihua Branch of Heilongjiang Academy of Agricultural Sciences, Suihua, Heilongjiang 152000

Received:2025-06-09 Revised:2025-07-15 Published:2025-07-25 Online:2025-08-05

摘要/Abstract

摘要：

本研究聚焦于水稻茎秆强度的遗传机制，旨在为抗倒伏分子育种提供坚实的理论依据。通过对学术文献以及研究报告进行系统的综述与深入的分析，阐述了茎秆强度、茎秆化学组成、激素调节以及株型相关基因的调控机制及其抗倒伏分子机理。分析结果显示，水稻茎秆强度受到形态结构（例如基部节间直径、壁厚）和化学成分（纤维素、半纤维素和木质素含量）的共同影响，其中下部节间的力学特性是决定水稻抗倒伏能力的关键因素。从基因层面来看，SCM3（OsTB1等位基因）借助独脚金内酯信号通路增强茎秆强度；WAK10对次生细胞壁纤维素的合成起到调控作用；OsTCP19促进木质素-纤维素的平衡；IPA1突变体则通过优化株型实现抗倒伏与高产的协同效应（减少无效分蘖、增加茎秆粗度，实现抗倒伏与穗粒数增加的平衡）。在育种应用方面，采用分子标记辅助选择的方法对相关QTL(quantitative trait loci)位点（如prl5、lrt5）进行筛选；利用基因编辑技术(CRISPR/Cas9)对茎秆强度关键基因进行定向改良；通过回交改良构建近等基因系聚合多个强秆基因（如SCM1-4）（NIL-SCM1、NIL-SCM2、NIL-SCM3和NIL-SCM4，以及双、三聚合体），成功培育出抗倒伏新品种‘Sakura prince’和‘Monster Rice 1’。本研究提出，未来应在以下几个方面开展工作：挖掘新型抗倒伏基因（如STRONG2模块），解析多基因协同效应；建立茎秆强度与穗重、穗数的遗传平衡模型；结合全基因组关联分析优化基因聚合策略；探究环境因子（台风、密植）对茎秆强度的影响规律等，以期实现水稻抗倒伏性与产量的同步提高。

关键词: 水稻, 茎秆强度, 激素调节, 育种应用

Abstract:

In this study, we focus on the genetic mechanisms underlying culm strength in rice, aiming to provide a robust theoretical foundation for molecular breeding of lodging-resistant varieties. By systematically reviewing and conducting in-depth analyses of academic literature and research reports, we explore the regulatory mechanisms of genes associated with culm strength, culm chemical composition, hormonal regulation, and plant architecture, as well as their molecular mechanisms in conferring lodging resistance. Consequently, rice culm strength is influenced by both morphological traits (e.g., basal internode diameter and culm wall thickness) and chemical components (including cellulose, hemicellulose, and lignin contents). Notably, the mechanical properties of lower internodes are key determinants of rice lodging resistance. In terms of genetics, SCM3 (an allele of OsTB1) enhances culm strength via the strigolactone signaling pathway. WAK10 regulates cellulose synthesis in secondary cell walls. OsTCP19 facilitates the balance between lignin and cellulose. IPA1 achieves synergistic improvements in lodging resistance and yield by optimizing plant architecture—specifically, by reducing ineffective tillers, increasing culm diameter, and balancing lodging resistance with an increased number of grains per panicle. In terms of breeding applications, molecular marker-assisted selection has been employed to screen for quantitative trait loci (QTLs) associated with culm strength, such as prl5 and lrt5. Additionally, gene-editing technologies (e.g., CRISPR/Cas9) have been utilized to modify key genes governing culm strength in rice lodging resistance breeding. Through backcrossing to develop near-isogenic lines (NILs), multiple strong culm genes (including SCM1-4) have been pyramided—resulting in NIL-SCM1, NIL-SCM2, NIL-SCM3, NIL-SCM4, as well as double and triple NIL combinations. This approach has enabled the successful development of lodging-resistant varieties, namely 'Sakura Prince' and 'Monster Rice 1'. This study proposes that future work should be carried out in the following aspects: mining novel lodging resistance genes (e.g., the STRONG2 module) and analyzing multi-gene synergistic effects, establishing a genetic balance model involving stem strength, panicle weight, and panicle number, optimizing gene pyramiding strategies in combination with genome-wide association analysis, and exploring the impacts of environmental factors (such as typhoons and dense planting) on culm strength. These efforts aim to achieve enhancement of rice lodging resistance and yield simultaneously.

Key words: rice, culm strength, hormone regulation, breeding application

常汇琳, 高世伟, 刘晴, 刘宇强, 马成, 沙汉景, 王婧泽, 聂守军. 水稻茎秆强度遗传研究进展[J]. 中国农学通报, 2025, 41(21): 36-42.

CHANG Huilin, GAO Shiwei, LIU Qing, LIU Yuqiang, MA Cheng, SHA Hanjing, WANG Jingze, NIE Shoujun. Genetic Research Progress of Rice Culm Strength[J]. Chinese Agricultural Science Bulletin, 2025, 41(21): 36-42.

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水稻茎秆强度遗传研究进展

Genetic Research Progress of Rice Culm Strength

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