丽江新团黑谷近等基因系抗稻瘟病分析

作物学报 ›› 2006, Vol. 32 ›› Issue (06): 799-804.

丽江新团黑谷近等基因系抗稻瘟病分析

付崇允;王玉平;马玉清;王玲霞;马炳田;李仕贵

四川农业大学水稻研究所, 四川温江611130；作物基因资源与遗传改良教育部重点实验室, 四川雅安625014

收稿日期:2005-05-30 修回日期:1900-01-01 出版日期:2006-06-12 网络出版日期:2006-06-12
通讯作者: 李仕贵

Identification of IRBL Near-isogenic Lines for Rice Blast Resistance

FU Chong-Yun,WANG Yu-Ping,MA Yu-Qing,WANG Li-Xia,MA Bing-Tian,LI Shi-Gui

Rice Research Institute, Sichuan Agriculture University, Wenjiang 611130, Sichuan; Key Laboratory of Crop Genetic Resources and Improvement/Sichuan Agricultural University, Ministry of Education, Ya’an 625014, Sichuan, China

Received:2005-05-30 Revised:1900-01-01 Published:2006-06-12 Published online:2006-06-12
Contact: LI Shi-Gui

摘要/Abstract

摘要：

利用31个稻瘟病菌株对由国际水稻研究所育成以不具有主效抗性基因的丽江新团黑谷为轮回亲本的一套单基因近等基因系和8个抗性基因组合进行接种鉴定，结果表明，不同抗性基因的抗谱存在显著差异，其中IRBLZ-Fu(Pi-z)、IRBLZ5-CA(Pi-z-5)、IRBLZt-T(Pi-z-t)、IRBL9-W(Pi-9(t))的抗性频率分别为93%、97％、90％和96％，可初步认为Pi-z、 Pi-z-5、 Pi-z-t、Pi-9(t)为广谱抗性基因；不同抗性基因组合的抗谱均较其亲本宽，主要表现为抗性基因间的互补效应和积加效应，本研究为基因聚合培育广谱持久的抗性品种提供了理论依据。

关键词: 稻瘟病, 近等基因系, 主效抗性基因, 抗性分析

Abstract:

To elucidate the resistance spectra of resistance genes and the feasibility of breeding the cultivar with durable and broad-spectrum resistance by integrating resistance genes, the monogenic NILs bred by IRRI with the background of LTH, a native variety in yunnan without any major resistance gene and their 8 combinations were identified by inoculating 31 Magnaporthe grisea isolates. The results indicated that the resistance spectra were remarkably different among the lines, and the resistance frequencies of IRBLZ-Fu(Pi-z), IRBLZ5-CA(Pi-z-5), IRBLZt-T(Pi-z-t), IRBL9-W(Pi-9(t)) were 93％，97％，90％ and 96％, respectively, showing that the four genes Pi-z, Pi-z-5, Pi-z-t, and Pi-9(t) were perceived preliminarily to be broad-spectrum resistance genes. At the same time, to avoid to the linkage, the resistance genes in different chromosomes were accumulated except for Pi-k-s and Pi-k-p. The resistance spectra of the combinations were broader than those of their parents because of complement effect and additive effect. Namely, on the one hand, the lines with single resistance gene were susceptible to some isolates, or some was susceptible, and some resistant, but the combination was resistant. On the other hand, some lines with single resistance gene and some combinations were susceptible to some isolates, but the size and the number of the lesion of the combinations were less than those of the lines with single resistance genes. Integrating several resistance genes into a cultivar would be useful for expanding resistance spectrum and durability. Pi-z, Pi-z-5, Pi-z-t and Pi-9(t) had great potential in resistance breeding, in spite of that the mechanism of their broad spectrum was not known. In addition, the resistance spectrum of the combination was broader than those of Pi-k-s and Pi-k-p. It’s not clear whether the mechanism of the broader spectrum was similar or same to the relation between EDS1 and PAD4 in Arabidopsis thaliana.

Key words: Rice blast, Near-isogenic line, Major resistance gene, Resistance identification

付崇允;王玉平;马玉清;王玲霞;马炳田;李仕贵. 丽江新团黑谷近等基因系抗稻瘟病分析[J]. 作物学报, 2006, 32(06): 799-804.

FU Chong-Yun;WANG Yu-Ping;MA Yu-Qing;WANG Li-Xia;MA Bing-Tian;LI Shi-Gui. Identification of IRBL Near-isogenic Lines for Rice Blast Resistance[J]. Acta Agron Sin, 2006, 32(06): 799-804.

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