节水抗旱稻恢复系的抗褐飞虱分子标记辅助选育及抗性评价

doi:10.3724/SP.J.1006.2019.82066

Abstract

Abstract:

The brown planthopper (Nilaparvata lugens St?l, BPH) is the most serious pest threat to rice production across Asia. Increasing host-plant resistance is the most economical and ecological strategy for controlling this pest. The objective of this study was to survey the resistance effects of different R genes to brown planthopper, reveal its influence on agronomic traits, and provide insights into molecular breeding of rice with resistance to brown planthopper. In this research, the brown planthopper R genes Bph6, Bph9, Bph14, and Bph15 were introgressed into the water-saving and drought-resistant rice restorer line ‘Hanhui 3’ through marker-assisted backcrossing scheme. The standard seedling group screening method was used to identify the resistance of the improved lines. Among single-gene improved lines, the order of the R genes effects was Bph9 > Bph6 > Bph15 > Bph14, and among pyramiding improved lines, that was Bph6+Bph9+Bph14+Bph15 > Bph6+Bph9 > Bph6+Bph9+Bph14 > Bph6+Bph9+Bph15 > Bph6+Bph14+Bph15 > Bph9+Bph14+Bph15 > Bph14+Bph15. Furthermore, the survey of agronomic traits demonstrated that there were no significant differences between the 11 improved lines and recurrent parent ‘Hanhui 3’ in plant height, panicle number per plant and 1000-grain weight. These results suggest that the introgression of Bph6, Bph9, Bph14, and Bph15 genes by molecular marker-assisted selection technology could enhance the resistance to brown planthopper and improve breeding efficiency.

Key words: breeding, brown planthopper, resistance gene, marker-assisted selection, resistance evaluation, water-saving and drought-resistance rice

ZHANG An-Ning,LIU Yi,WANG Fei-Ming,XIE Yue-Wen,KONG De-Yan,NIE Yuan-Yuan,ZHANG Fen-Yun,BI Jun-Guo,YU Xin-Qiao,LIU Guo-Lan,LUO Li-Jun. Pyramiding and evaluation of brown planthopper resistance genes in water-saving and drought-resistance restorer line[J].Acta Agronomica Sinica, 2019, 45(11): 1764-1769.

Figures/Tables 4

Fig. 1

Fig. 2

Table 1

Table 2

References 23

[1]	Khush G S . What it will take to feed 5.0 billion rice consumers in 2030. Plant Mol Biol, 2005,59:1-6.
[2]	Xue J, Zhou X, Zhang C X, Yu L L, Fan H W, Wang Z, Xu H J, Xi Y, Zhu Z R, Zhou W W, Pan P L, Li B L, Colbourne J K, Noda H, Suetsugu Y, Kobayashi T, Zheng Y, Liu S, Zhang R, Liu Y, Luo Y D, Fang D M, Chen Y, Zhan D L, Lyu X D, Cai Y, Wang Z B, Huang H J, Cheng R L, Zhang X C, Lou Y H, Yu B, Zhuo J C, Ye Y X, Zhang W Q, Shen Z C, Yang H M, Wang J, Bao Y Y, Cheng J A . Genomes of the rice pest brown planthopper and its endosymbionts reveal complex complementary contributions for host adaptation. Genome Biol, 2014,15:521.
[3]	姜辉, 林荣华, 刘亮, 瞿唯钢, 陶传江 . 稻飞虱的危害及再猖獗机制. 昆虫知识, 2005,42:612-615.
	Jiang H, Lin R H, Liu L, Qu W G, Tao C J . Planthoppers damage to rice and the resurgence mechanism. Chin Bull Entomol, 2005,42:612-615 (in Chinese with English abstract).
[4]	Heong K L, Hardy B . Planthoppers: New Threats to the Sustainability of Intensive Rice Production Systems in Asia. Los Baños (Philippines): International Rice Research Institute, 2009. pp 401-428.
[5]	Hu J, Xiao C, He Y . Recent progress on the genetics and molecular breeding of brown planthopper resistance in rice. Rice, 2016,9:30.
[6]	Huang Z, He G, Shu L, Li X, Zhang Q . Identification and mapping of two brown planthopper resistance genes in rice. Theor Appl Genet, 2001,102:929-934.
[7]	Guo J P, Xu C X, Wu D, Zhao Y, Qiu Y F, Wang X X, Ou-Yang Y D, Cai B D, Liu X, Jing S L, Shang-Guan X X, Wang H Y, Ma Y H, Hu L, Wu Y, Shi S J, Wang W L, Zhu L L, Xu X, Chen R Z, Feng Y Q, Du B, He G C . Bph6 encodes an exocyst-localized protein and confers broad resistance to planthoppers in rice. Nat Genet, 2018,50:297-306.
[8]	Zhao Y, Huang J, Wang Z Z, Jing S L, Wang Y, Ou-Yang Y D, Cai B D, Xin X F, Liu X, Zhang C X, Pan Y F, Ma R, Li Q F, Jiang W H, Zeng Y, Shang-Guan X X, Wang H Y, Du B, Zhu L L, Xu X, Feng Y Q, He S Y, Chen R Z, Zhang Q F, He G C . Allelic diversity in an NLR gene Bph9 enables rice to combat planthopper variation. Proc Natl Acad Sci USA, 2016,113:12850-12855.
[9]	陈英之, 陈乔, 孙荣科, 杨朗, 黄凤宽, 黄大辉, 韦素美, 张月雄, 刘丕庆, 李容柏 . 改良水稻对稻褐飞虱的抗性研究. 西南农业学报, 2010,23:1099-1106.
	Chen Y Z, Chen Q, Sun R K, Yang L, Huang F K, Huang D H, Wei S M, Zhang Y X, Liu P Q, Li R B . Improvement of rice resistance to brown planthoppers. Southwest China J Agric Sci, 2011,23:1099-1106 (in Chinese with English abstract).
[10]	胡杰, 杨长举, 张庆路, 高冠军, 何予卿 . 基因聚合改良杂交稻组合的稻飞虱田间抗性表现. 应用昆虫学报, 2011,48:1341-1347.
	Hu J, Yang C J, Zhang Q L, Gao G J, He Y Q . Resistance of pyramided rice hybrids to brown planthoppers. Chin J Appl Entomol, 2011,48:1341-1347 (in Chinese with English abstract).
[11]	李进波, 夏明元, 戚华雄, 何光存, 万丙良, 查中萍 . 水稻抗褐飞虱基因Bph14和Bph15的分子标记辅助选择. 中国农业科学, 2006,39:2132-2137.
	Li J B, Xia M Y, Qi H X, He G C, Wan B L, Zha Z P . Marker-assisted selection for brown planthopper (Nilaparvata lugens Stål) resistance gene Bph14 and Bph15 in rice. Sci Agric Sin, 2006,39:2132-2137 (in Chinese with English abstract).
[12]	李进波, 万丙良, 夏明元, 戚华雄, 石华胜, 辛复林 . 抗褐飞虱水稻品种的培育及其抗性表现. 应用昆虫学报, 2011,48:1348-1353.
	Li J B, Wan B L, Xia M Y, Qi H X, Shi H S, Xin F L . Breeding of the brown planthopper resistant rice varieties. Chin J Appl Entomol, 2011,48:1348-1353 (in Chinese with English abstract).
[13]	罗世友, 陈红萍, 吴小燕, 胡兰香, 熊换金, 邓伟, 汪雨萍, 席建才, 喻凤, 陈明亮, 肖叶青, 陈大洲 . 应用分子标记辅助选育抗褐飞虱水稻恢复系. 分子植物育种, 2015,13:2404-2415.
	Luo S Y, Chen H P, Wu X Y, Hu L X, Xiong H J, Deng W, Wang Y P, Xi J C, Yu F, Chen M L, Xiao Y Q, Chen D Z . Breeding restorer lines resistance to brown planthopper by marker-assisted selection. Mol Plant Breed, 2015,13:2404-2415 (in Chinese with English abstract).
[14]	罗利军, 梅捍卫, 余新桥, 刘鸿艳, 冯芳君 . 节水抗旱稻及其发展策略. 科学通报, 2011,56:804-811.
	Luo L J, Mei H W, Yu X Q, Liu H Y, Feng F J . Water-saving and drought-resistance rice and its development strategy. Chin Sci Bull, 2011,56:804-811 (in Chinese with English abstract).
[15]	聂元元, 李霞, 毛凌华, 赵洪阳, 万鹏, 李瑶 . 节水抗旱稻在江西的试验示范及推广. 杂交水稻, 2018,33(2):38-39.
	Nie Y Y, Li X, Mao L H, Zhao H Y, Wan P, Li Y . Experimental demonstration and extension of water-saving and drought-resistant rice in Jiangxi. Hybrid Rice, 2018,32(2):38-39 (in Chinese).
[16]	王震, 徐爱民, 朱敬乐, 赵洪阳 . 节水抗旱稻“旱优73”在蚌埠的示范表现及高产栽培技术. 安徽农学通报, 2018,24(2):42-44.
	Wang Z, Xu A M, Zhu J L, Zhao H Y . Performance of water- saving and drought-resistant rice ‘Hanyou 73’ in Bengbu. Anhui Agric Sci Bull, 2018,24(2):42-44 (in Chinese).
[17]	柏秀芳, 贾琳, 胡超, 李柱, 周娟, 符建法, 贾先勇 . 节水抗旱稻在湖南的发展前景与策略. 湖南农业科学, 2016, ( 8):25-27.
	Bai X F, Jia L, Hu C, Li Z, Zhou J, Fu J F, Jia X Y . Development prospect and strategies of water-saving and drought-resistance rice in Hunan. Hunan Agric Sci, 2016, ( 8):25-27 (in Chinese with English abstract).
[18]	Jena K K, Hechanova S L, Verdeprado H, Prahalada G D, Kim S R . Development of 25 near-isogenic lines (NILs) with ten BPH resistance genes in rice (Oryza sativa L.): production, resistance spectrum, and molecular analysis. Theor Appl Genet, 2017,130:2345-2360.
[19]	Xiao C, Hu J, Ao Y T, Cheng M X, Gao G J, Zhang Q L, He G C, He Y Q . Development and evaluation of near-isogenic lines for brown planthopper resistance in rice cv. 9311. Sci Rep, 2016,6:38159.
[20]	Qiu Y F, Guo J P, Jing S L, Zhu L L, He G C . Development and characterization of japonica rice lines carrying the brown planthopper-resistance genes Bph12 and Bph6. Theor Appl Genet, 2012,124:485-894.
[21]	曾盖 . 利用MAS改良水稻两用核不育系的稻瘟病和褐飞虱抗性. 湖南农业大学硕士学位论文, 2017. pp 22-30.
	Zeng G . Improving Blast and BPH Resistance of Dual-purpose Genic Sterile Rice Using Molecular Marker-assisted Selection. MS Thesis of Hunan Agricultural University, Changsha, Hunan, China, 2017. pp 22-30 (in Chinese with English abstract).
[22]	胡杰 . 水稻褐飞虱抗性基因的遗传定位和聚合效应分析. 华中农业大学博士学位论文, 湖北武汉, 2013. pp 85-92.
	Hu J . Mapping and Pyramiding Brown Planthopper Resistance Genes in Rice. PhD Dissertation of Huazhong Agricultural University, Wuhan, Hubei, China, 2013. pp 85-92 (in Chinese with English abstract).
[23]	楼珏, 杨文清, 李仲惺, 罗天宽, 谢永楚, 郑国楚, 岳高红, 徐建龙, 卢华金 . 聚合稻瘟病、白叶枯病和褐飞虱抗性基因的三系恢复系改良效果的评价. 作物学报, 2016,42:31-42.
	Lou J, Yang W Q, Li Z X, Luo T K, Xie Y C, Zheng G C, Yue G H, Xu J L, Lu H J . Evaluation of improvement effect of restorer lines on pyramiding genes resistant to rice blast, bacterial leaf blight and brown planthopper. Acta Agron Sin, 2016,42:31-42 (in Chinese with English abstract).

Related Articles 15

[1]	HU Wen-Jing, LI Dong-Sheng, YI Xin, ZHANG Chun-Mei, ZHANG Yong. Molecular mapping and validation of quantitative trait loci for spike-related traits and plant height in wheat [J]. Acta Agronomica Sinica, 2022, 48(6): 1346-1356.
[2]	DENG Zhao, JIANG Nan, FU Chen-Jian, YAN Tian-Zhe, FU Xing-Xue, HU Xiao-Chun, QIN Peng, LIU Shan-Shan, WANG Kai, YANG Yuan-Zhu. Analysis of blast resistance genes in Longliangyou and Jingliangyou hybrid rice varieties [J]. Acta Agronomica Sinica, 2022, 48(5): 1071-1080.
[3]	ZHU Zheng, WANG Tian-Xing-Zi, CHEN Yue, LIU Yu-Qing, YAN Gao-Wei, XU Shan, MA Jin-Jiao, DOU Shi-Juan, LI Li-Yun, LIU Guo-Zhen. Rice transcription factor WRKY68 plays a positive role in Xa21-mediated resistance to Xanthomonas oryzae pv. oryzae [J]. Acta Agronomica Sinica, 2022, 48(5): 1129-1140.
[4]	YANG Xin, LIN Wen-Zhong, CHEN Si-Yuan, DU Zhen-Guo, LIN Jie, QI Jian-Min, FANG Ping-Ping, TAO Ai-Fen, ZHANG Li-Wu. Molecular identification of a geminivirus CoYVV and screening of resistant germplasms in jute [J]. Acta Agronomica Sinica, 2022, 48(3): 624-634.
[5]	MA Hong-Bo, LIU Dong-Tao, FENG Guo-Hua, WANG Jing, ZHU Xue-Cheng, ZHANG Hui-Yun, LIU Jing, LIU Li-Wei, YI Yuan. Application of Fhb1 gene in wheat breeding programs for the Yellow-Huai Rivers valley winter wheat zone of China [J]. Acta Agronomica Sinica, 2022, 48(3): 747-758.
[6]	ZHAO Mei-Cheng, DIAO Xian-Min. Phylogeny of wild Setaria species and their utilization in foxtail millet breeding [J]. Acta Agronomica Sinica, 2022, 48(2): 267-279.
[7]	ZHAO Hai-Han, LIAN Wang-Min, ZHAN Xiao-Deng, XU Hai-Ming, ZHANG Ying-Xin, CHENG Shi-Hua, LOU Xiang-Yang, CAO Li-Yong, HONG Yong-Bo. Genetic dissection of the bacterial blight disease resistance in super hybrid rice RILs using genome-wide association study [J]. Acta Agronomica Sinica, 2022, 48(1): 121-137.
[8]	XI Ling, WANG Yu-Qi, ZHU Wei, WANG Yi, CHEN Guo-Yue, PU Zong-Jun, ZHOU Yong-Hong, KANG Hou-Yang. Identification of resistance to wheat and molecular detection of resistance genes to wheat stripe rust of 78 wheat cultivars (lines) in Sichuan province [J]. Acta Agronomica Sinica, 2021, 47(7): 1309-1323.
[9]	HAN Yu-Zhou, ZHANG Yong, YANG Yang, GU Zheng-Zhong, WU Ke, XIE Quan, KONG Zhong-Xin, JIA Hai-Yan, MA Zheng-Qiang. Effect evaluation of QTL Qph.nau-5B controlling plant height in wheat [J]. Acta Agronomica Sinica, 2021, 47(6): 1188-1196.
[10]	JIANG Wei, PAN Zhe-Chao, BAO Li-Xian, ZHOU Fu-Xian, LI Yan-Shan, SUI Qi-Jun, LI Xian-Ping. Genome-wide association analysis for late blight resistance of potato resources [J]. Acta Agronomica Sinica, 2021, 47(2): 245-261.
[11]	ZHANG Rong-Yue, WANG Xiao-Yan, YANG Kun, SHAN Hong-Li, CANG Xiao-Yan, LI Jie, WANG Chang-Mi, YIN Jiong, LUO Zhi-Ming, LI Wen-Feng, HUANG Ying-Kun. Identification of brown rust resistance and molecular detection of Bru1 gene in new and main cultivated sugarcane varieties [J]. Acta Agronomica Sinica, 2021, 47(2): 376-382.
[12]	ZHANG Huan, LUO Huai-Yong, LI Wei-Tao, GUO Jian-Bin, CHEN Wei-Gang, ZHOU Xiao-Jing, HUANG Li, LIU Nian, YAN Li-Ying, LEI Yong, LIAO Bo-Shou, JIANG Hui-Fang. Genome-wide identification of peanut resistance genes and their response to Ralstonia solanacearum infection [J]. Acta Agronomica Sinica, 2021, 47(12): 2314-2323.
[13]	HUANG Yi-Wen, DAI Xu-Ran, LIU Hong-Wei, YANG Li, MAI Chun-Yan, YU Li-Qiang, YU Guang-Jun, ZHANG Hong-Jun, LI Hong-Jie, ZHOU Yang. Relationship between the allelic variations at the Ppo-A1 and Ppo-D1 loci and pre-harvest sprouting resistance in wheat [J]. Acta Agronomica Sinica, 2021, 47(11): 2080-2090.
[14]	CHE Yang, CHENG Shuang, TIAN Jin-Yu, TAO Yu, LIU Qiou-Yuan, XING Zhi-Peng, DOU Zhi, XU Qiang, HU Ya-Jie, GUO Bao-Wei, WEI Hai-Yan, GAO Hui, ZHANG Hong-Cheng. Characteristics and differences of rice yield, quality, and economic benefits under different modes of comprehensive planting-breeding in paddy fields [J]. Acta Agronomica Sinica, 2021, 47(10): 1953-1965.
[15]	ZHAO Xu-Yang, YAO Fang-Jie, LONG Li, WANG Yu-Qi, KANG Hou-Yang, JIANG Yun-Feng, LI Wei, DENG Mei, LI Hao, CHEN Guo-Yue. Evaluation of resistance to stripe rust and molecular detection of resistance genes of 93 wheat landraces from the Qinghai-Tibet spring and winter wheat zones [J]. Acta Agronomica Sinica, 2021, 47(10): 2053-2063.

Metrics

Viewed

Full text

848

HTML			PDF

Just accepted	Online first	Issue	Just accepted	Online first	Issue
0	0	11	0	0	837

From	Others	local

Times	62	786
Rate	7%	93%

Abstract

865

Just accepted	Online first	Issue

0	0	865

From	Others	local

Times	141	724
Rate	16%	84%

Cited

Web of Science	Crossref	ScienceDirect	Search for Citations in Google Scholar >>


This page requires you have already subscribed to WoS.

Shared

Discussed

Comments

Recommended 0

No Suggested Reading articles found!

编号 No.	鉴定编号 Identification no.	基因型 Genotype	抗性表现 Resistance performance	抗性级别 Resistance level^#
18R1	18FS30	Bph6	2.60±0.81	抗虫	R
18R2	18FS72	Bph9	2.40±0.35	抗虫	R
18R3	18FS32	Bph14	5.20±0.76	中抗	MR
18R4	18FS71	Bph15	4.30±0.97	中抗	MR
18R5	18FS86	Bph6+Bph9	1.10±0.21	高抗	HR
18R6	18FS83	Bph14+Bph15	1.93±0.41	高抗	HR
18R7	18FS90	Bph6+Bph9+Bph14	1.27±0.27	高抗	HR
18R8	18FS88	Bph6+Bph9+Bph15	1.50±0.38	高抗	HR
18R9	18FS92	Bph6+Bph14+Bph15	1.60±0.31	高抗	HR
18R10	18FS94	Bph9+Bph14+Bph15	1.70±0.35	高抗	HR
18R11	18FS97	Bph6+Bph9+Bph14+Bph15	0.53±0.24	高抗	HR
旱恢3号 Hanhui 3	18FS26		8.93±0.07	高感	HS
TN1			8.80±0.12	高感	HS

编号 No.	基因型 Genotype	株高 Plant height (cm)	单株有效穗 Panicles per plant	穗长 Panicle length (cm)	每穗总粒数 Grains per panicle	结实率 Grain fertility (%)	千粒重 1000-Grain weight (g)	单株产量 Grain yield per plant (g)
18R1	Bph6	121.00±1.00	13.67±3.21	21.49±0.58	200.30±2.84^**	83.35±3.04	26.35±0.88	32.34±0.70^*
18R2	Bph9	119.68±1.64	9.88±0.55	25.53±0.87^**	202.65±5.16^**	77.62±1.78	24.79±1.66	33.94±1.74
18R3	Bph14	129.00±6.24	10.00±4.00	24.88±1.80	199.98±7.81^**	90.37±1.14	25.00±1.20	29.04±0.73^**
18R4	Bph15	120.48±1.36	10.70±1.00	26.13±0.45^**	200.22±3.20^**	79.16±2.39	24.32±0.54	34.94±1.47
18R5	Bph6+Bph9	120.65±2.67	10.58±0.64	25.75±0.57^**	201.66±2.29^**	76.68±0.98^*	24.44±1.58	31.99±3.46^*
18R6	Bph14+Bph15	119.71±2.21	9.88±0.64	26.08±0.49^**	198.87±7.43^**	80.37±1.66	26.07±1.82	30.64±1.71^**
18R7	Bph6+Bph9+Bph14	118.12±1.46	10.50±1.04	24.90±0.48^*	194.34±2.80^**	71.64±1.30^**	26.21±1.12	34.90±0.71
18R8	Bph6+Bph9+Bph15	124.19±0.13	10.04±0.69	25.13±0.85^*	205.54±5.21^**	71.86±1.73^**	24.44±0.88	32.75±2.89
18R9	Bph6+Bph14+Bph15	119.89±1.59	10.95±0.23	24.94±0.61^*	200.59±4.13^**	68.69±1.13^**	24.87±1.73	36.47±1.04
18R10	Bph9+Bph14+Bph15	118.41±3.68	10.99±0.53	26.14±0.62^**	201.56±2.44^**	69.90±3.57^**	26.53±0.52	31.19±1.82^*
18R11	Bph6+Bph9+Bph14+Bph15	121.12±2.63	11.33±0.56	25.82±0.36^**	200.79±6.06^**	57.26±2.73^**	26.40±1.21	30.38±1.89^**
Hanhui 3		117.00±4.90	10.00±0.82	22.80±0.41	240.69±21.35	86.24±6.49	25.84±1.62	42.11±6.78

Pyramiding and evaluation of brown planthopper resistance genes in water-saving and drought-resistance restorer line

RichHTML358

PDF