籼型三系不育系'福农A'的选育及其综合农艺性状分析

doi:10.3969/j.issn.1674-7968.2024.03.019

Abstract
Figure/Table
References
Related Citation (1)

Download: PDF (7612 KB) HTML (1 KB)
Export: BibTeX | EndNote (RIS)

Abstract The cytoplasmic male sterile line (CMS) is one of the important prerequisites for breeding superior hybrid rice (Oryza sativa) varieties, cultivating excellent CMS is of great significance for hybrid rice breeding. In this study, the high-resistant and high-quality rice variety 'Huahang Simiao' was used as the donor parent, and it was crossed with the Indica three-line maintainer line 'Fudao B', which had good comprehensive agronomic traits but poor grain quality and rice blast resistance. In the F₃ generation, superior plants were selected as male parents and crossed with 'Gufeng A' as the female parent. The progeny from the crosses were continuously subjected to shuttle breeding and selection in Sanya and Shaxian bases. After multiple generations of elimination and selection, a stable CMS line named 'Funong A' was finally bred, and its corresponding maintainer line was named 'Funong B'. Comprehensive analysis of agronomic traits revealed that 'Funong A' had good leaf morphology, sturdy stems, and erect flag leaves, with a morning flowering ratio of 85%. The stem diameter and thickness of 'Funong A' were significantly larger than those of the parent lines. Field tests and microscopic observations showed that the sterility rate of 'Funong A' was 100%, pollen sterility ratio was 99.99%, and stigma exsertion rate was 57.12%. 'Funong A' exhibited a significantly larger basal internode diameter and thicker stem wall, as well as higher content of hemicellulose and silicon in stems. High-density chip analysis revealed the presence of semi-dwarf gene Sd-1, spikelet development-related gene qNGR9, and grain weight gene OsSPL16 in 'Funong A'. Additionally, Funong A successfully combined 3 rice blast resistance genes, Pi5, Pid2, and Pid3, with an indoor identification rate of resistant strains reaching 81.82%. Moreover, the 7 rice varieties developed using 'Funong A' exhibited high yield, good grain quality, and intermediate resistance to rice blast disease. It is evident that 'Funong A' possesses strong development potential and can provide support for the combination and breeding of hybrid rice with good resistance, high yield, and superior rice quality.

Key words： Indica cytoplasmic male sterile line 'Funong A' Rice blast resistance Comprehensive agronomic trait

Received: 28 September 2023

ZTFLH:

S334.5

Corresponding Authors: * jianfzhang@163.com

	Service

	E-mail this article
	Add to my bookshelf
	Add to citation manager
	E-mail Alert
	RSS
	Articles by authors
	TU Shi-Hang
	LIAN Ling
	HONG Yong-He
	ZHOU Peng
	ZHENG Fei-Yan
	ZHENG Jia-Tuan
	ZHANG Jian-Fu

Cite this article:

TU Shi-Hang,LIAN Ling,HONG Yong-He, et al. Breeding of the Three-line Indica Cytoplasmic Male Sterile Line 'Funong A' and Its Comprehensive Agronomic Trait Analysis[J]. 农业生物技术学报, 2024, 32(3): 701-711.

URL:

https://journal05.magtech.org.cn/Jwk_ny/EN/10.3969/j.issn.1674-7968.2024.03.019 OR https://journal05.magtech.org.cn/Jwk_ny/EN/Y2024/V32/I3/701

[1] 蔡克锋, 马荣荣, 王晓燕, 等. 2018. 早熟晚粳不育系甬粳43A的选育[J]. 杂交水稻, 33(2): 21-23.
(Cai K F, Ma R R, Wang X Y, et al.2018. Breeding of early-maturing late japonica CMS line Yongjing 43A in rice[J]. Hybrid Rice, 33(2): 21-23.)
[2] 傅再水. 2016. 杂交水稻不育系深95A秋繁高产技术[J]. 福建稻麦科技, 34(1): 14-16.
(Fu Z S.2016. High yielding techniques for autumn propagation of hybrid rice sterile line Shen 95A[J]. Fujian Science and Technology of Rice and Wheat, 34(1): 14-16.)
[3] 郭玉华, 朱四光, 张龙步, 等. 2003. 不同栽培条件对水稻茎秆材料学特性的影响[J]. 沈阳农业大学学报, 34(1): 4-7.
(Guo Y H, Zhu S G, Zhang L B, et al.Influence on the material characteristics of rice culms in different cultivation conditions[J]. Journal of Shenyang Agricultural University, 34(1): 4-7.)
[4] 江青山, 林纲, 赵德明, 等. 2008. 优质香稻不育系宜香1A的选育与利用[J]. 杂交水稻, 23(2): 11-14.
(Jiang Q S, Lin G, Zhao D M, et al.2008. Breeding and utilization of aromatic indica rice CMS line Yixiang 1A with good grain quality[J]. Hybrid Rice, 23(2): 11-14.)
[5] 江云珠, 沈希宏, 曹立勇. 2012. 水稻茎秆性状的研究进展[J]. 中国稻米, 18(2): 1-7.
(Jiang Y Z, Shen X H, Cao LY.Research progress of stem traits in rice[J]. China Rice, 18(2): 1-7.)
[6] 鞠涛. 2003. 水稻稻瘟病防治方法研究进展[J]. 新农业, (8): 8-9.
(Ju T. 2003. Advances in research on control method of rice blast[J]. Modern Agriculture, (8): 8-9.)
[7] 莫海玲, 唐梅, 孙富, 等. 2015. 优质香稻三系不育系野香A的选育与应用[J]. 杂交水稻, 30(4): 11-12.
(Mo H L, Tang M, Sun F, et al.2015. Breeding and application of high quality aromatic rice CMS line Yexiang A[J]. Hybrid Rice, 30(4): 11-12.)
[8] 伍中胜, 刘大锷, 王建龙, 等. 2015. 优质籼型三系不育系桃农1A的选育与应用[J]. 杂交水稻, 30(4): 6-8.
(Wu Z S, Liu D E, Wang J L, et al.2015. Breeding and application of high quality indica CMS line Taonong 1A[J]. Hybrid Rice, 30(4): 6-8.)
[9] 曾波, 龚俊义, 张芳. 2022. 我国优质杂交稻主要品种推广情况与展望[J]. 中国水稻科学, 36(5):439-446.
(Zeng B, Gong J Y, Zhang F.2022. Analysis and prospects of extension of main varieties of hybrid rice with high quality in China[J]. Chinese Journal of Rice Science, 36(5): 439-446.)
[10] 张卫星, 马晨怡, 袁玉伟, 等. 2021. 我国水稻三大优势产区稻米品质现状及区域差异[J]. 中国稻米, 27(5): 12-18.
(Zhang W X, Ma C Y, Yuan Y W, et al.2021. Current situation and regional difference of rice grain quality in three rice-production superiority areas of China[J]. China Rice, 27(5): 12-18.)
[11] 周隆, 李永明. 1989. 珍汕97A春繁单产实现新突破[J]. 杂交水稻, (5): 17-19.
(Zhou L, Li Y M. 1989. ZhenshanA achieves a new breakthrough in single crop yield during spring season[J]. Hybrid Rice, (5): 17-19.)
[12] 朱英国. 2016. 杂交水稻研究50年[J]. 科学通报, 61(35): 3740-3747.
(Zhu Y G.2016. Fifty years of hybrid rice research in China[J]. Chinese Science Bulletin, 61(35): 3740-3747.)
[13] Asibi A E, Chai Q, Coulter J A.2019. Rice Blast: A disease with implications for global food security[J]. Agronomy, 9(8): 451.
[14] Chai R, Wang J, Wang X, et al.2022. The Pid family has been diverged into Xian and Geng type resistance genes against rice blast disease[J]. Genes (Basel), 13(5): 891.
[15] Lee S K, Song M Y, Seo Y S, et al.2009. Rice Pi5-mediated resistance to Magnaporthe oryzae requires the presence of two coiled-coil-nucleotide-binding-leucine-rich repeat genes[J]. Genetics, 181(4): 1627-38.
[16] Kato H.2001. Rice blast disease[J]. Pestic, Outlook, 12: 23-25.
[17] Shang J, Tao Y, Chen X, et al.2009. Identification of a new rice blast resistance gene, Pid3, by genome wide comparison of paired nucleotide-binding site--leucine-rich repeat genes and their pseudogene alleles between the two sequenced rice genomes[J]. Genetics, 182(4): 1303-1311.
[18] Wang R, Ning Y, Shi X, et al.2016. Immunity to rice blast disease by suppression of effector-triggered necrosis[J]. Current Biology, 26(18): 2399-411.
[19] Wang X, Lee S, Wang J, et al.2014. Current advances on genetic resistance to rice blast disease[M]. Rice-Germplasm, Genetics and Improvement.
[20] Zhang F, Fang H, Wang M, et al.2022. APIP5 functions as a transcription factor and an RNA-binding protein to modulate cell death and immunity in rice[J]. Nucleic Acids Research, 50(9): 5064-5079.