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Acta Agron Sin ›› 2013, Vol. 39 ›› Issue (06): 999-1012.doi: 10.3724/SP.J.1006.2013.00999

• CROP GENETICS & BREEDING·GERMPLASM RESOURCES·MOLECULAR GENETICS • Previous Articles     Next Articles

Reaction of Wheat-Thinopyrum Progenies and Wheat Germplasm to Sharp Eyespot

LI Hong-Jie1,*,WANG Xiao-Ming1,CHEN Huai-Gu2,LI Wei2,LIU Dong-Tao3,ZHANG Hui-Yun3   

  1. 1 Institute of Crop Sciences, Chinese Academy of Agricultural Sciences / National Key Facility for Crop Gene Resources and Genetic Improvement, Beijing 100081, China; 2 Institute of Plant Protection, Jiangsu Academy of Agricultural Sciences, Nanjing 210014, China; 3 Institute of Agricultural Sciences of Xuzhou, Xuzhou 221121, China?
  • Received:2012-12-04 Revised:2013-03-11 Online:2013-06-12 Published:2013-03-22

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Abstract:

The objectives of this study were to test reactions of wheat-Thinopyrum derivatives and wheat (Triticum aestivum L.) cultivars and breeding lines to sharp eyespot (caused by Rhizoctonia cerealis Van der Hoeven) and to understand the relationship between Thinopyrum chromosomes and sharp eyespot resistance. Using field nursery tests, 321 common wheat accessions and 56 wheat-Thinopyrum derivatives were tested in Xuzhou and Nanjing, Jiangsu Province, China. In Xuzhou, none of the accessions was highly resistant, while 52 accessions (including 34 common wheat accessions) were moderately resistant. Six common wheat cultivars, i.e., Xiaonong 8506-1, Xiaoyan 81, Jizhi 4001, Nongda 195, Xuzhou 8913, and Jingdong 3066A-3, had the relative resistance index greater than 0.7. In Nanjing, all the common wheat entries were moderately or highly susceptible. Only five accessions in wheat-Thinopyrum progenies showed moderately resistant reaction. The chromosome addition, substitution, and translocation lines TA3513, TA3516, TA351, and TA3519 involving chromosome 4Ai#2 or 4Ai#2S of Th. intermedium and the chromosome substitution line SS767 involving homoeologous group 4 chromosome of Th. ponticum had the disease indexes smaller than the susceptible controls Sumai 3 and Yangmai 158, as well the moderately resistant controls Annong 8455 and Ningmai 9. This indicated that the homoeologous group 4 chromosomes from Th. intermedium and Th. ponticum were most likely associated with the reduction of disease indexes. Genomic in situ hybridization using St genomic DNA from Pseudoroegneria strigos as a probe demonstrated that chromosome 4Ai#2 belongs to Js genome of Th. intermedium and the homoeologous group 4 chromosome of Th. ponticum belongs to J genome. Although sharp eyespot and eyespot develop similar shapes of symptoms on the basal stems of wheat, the eyespot resistance genes Pch1 and Pch2 carried by the wheat cultivars Madsen and Cappelle-Desprez, respectively, were not effective against sharp eyespot.

Key words: Triticum aestivum, Thinopyrum intermedium, Thinopyrum ponticum, Sharp eyespot, Disease resistance

[1]Hamada M S, Yin Y N, Chen H G, Ma Z H. The escalating threat of Rhizoctonia cerealis, the causal agent of sharp eyespot in wheat. Pest Manag Sci, 2011, 67: 1411–1419



[2]Pitt D. Studies on sharp eyespot disease of cereals: Effects of the disease on the wheat host and the incidence of disease in the field. Ann Appl Biol, 1966, 58: 299–308



[3]Richardson M J, Whittle A M, Jacks M. Yield loss relationships in cereals. Plant Pathol, 1976, 25: 21–30



[4]Clarkson J D S, Cook R J. Effect of sharp eyespot (Rhizoctonia cerealis) on yield loss in winter wheat. Plant Pathol, 1983, 32: 421–428



[5]Cromey M G, Butler R C, Boddington H J, Moorhead A R. Effects of sharp eyespot on yield of wheat (Triticum aestivum) in New Zealand. New Zealand J Crop Hort Sci, 2002, 30: 9–17



[6]Lemańczyk G, Kwa?na H. Effect of sharp eyespot (Rhizoctonia cerealis) on yield and grain quality of winter wheat. Eur J Plant Pathol, 2012, 135: 187–200



[7]Davies W P, Price K R. Sensitivity of sharp eyespot of wheat and Rhizoctonia cerealis to fungicides. Ann Appl Biol, 1983, 102: 54–55



[8]Matthews A B, Gold K, Davies W P. Response of true eyespot and sharp eyespot of wheat to fungicides. Ann Appl Biol, 1985, 106: 76–77



[9]Chen H G, Gao Q G, Xiong G L, Li W, Zhang A X, Yu H S, Wang J S. Composition of wheat rhizosphere antagonistic bacteria and wheat sharp eyespot as affected by rice straw mulching. Pedosphere, 2010, 20: 505–514



[10]Jiang L-L(姜莉莉), Qiao K(乔康). Research status of wheat sharp eyespot resistance to fungicides. Agrochem Res Appl (农药研究与应用), 2010, 14(3): 11–14 (in Chinese with English abstract)



[11]Hamada M S, Yin Y N, Ma Z H. Sensitivity to iprodione, difenoconazole and fludioxonil of Rhizoctonia cerealis isolates collected from wheat in China. Crop Prot, 2011, 30: 1028–1033



[12]Xia X-M(夏晓明), Wang K-Y(王开运), Wang H-X(王怀训), Liu Y-H(刘英华), Hu Y(胡燕), Fan X(范昆). Studies on resistance risk forecast to validamycin against Rhizoctonia cerealis. Chin J Pestc Sci (农药学学报), 2006, 8(2): 115–120 (in Chinese with English abstract)



[13]Guo C-Q(郭春强), Liao P-A(廖平安), Ge C-B(葛昌斌), He D-X(贺德先), Zang H-Z(臧贺藏), Guo S-J(郭松景), Huang Q-M(黄全民), Chen Q(陈琦). Effects of main agronomic measures on reducing disease index of sharp eyespot in wheat (Triticum aestivum L.). J Triticeae Crops (麦类作物学报), 2008, 28(3): 537–540 (in Chinese with English abstract)



[14]Matusinsky P, Mikolasova R, Klem K, Spitzer T, Urban T. The role of organic vs. conventional farming practice, soil management and preceding crop on the incidence of stem-base pathogens on wheat. J Plant Dis Prot, 2008, 115: 17–22



[15]Wan Y-X(万映秀), Wang W-X(王文相), Zhang P-Z(张平治), Cao W-X(曹文昕), Zhao L(赵莉). Identification techniques and screening of sharp eyespot resistance of wheat. Chin Agric Sci Bull (中国农学通报), 2009, 25(7): 223–226 (in Chinese with English abstract)



[16]Li S-S(李斯深), Wang H-G(王洪刚), Liu A-X(刘爱新), Li X-B(李宪彬), Li A-F(李安飞), Liu S-B(刘树兵). Identification and genetic analysis of resistance to sharp eyespot (Rhizoctonia cerealis) in winter wheat germplasm. Acta Bot Boreali-Occident Sin (西北植物学报), 2001, 21(5): 1004–1008 (in Chinese with English abstract)



[17]Yang L-J(杨立军), Yang X-J(杨小军), Yu D-Z(喻大昭), Wang S-N(王绍南). Resistance evaluation of wheat cultivars (lines) to Rhizoctonia cerealis Van der Hoeven and screening of its resistance resources. Plant Prot (植物保护), 2001, 27(2): 4–7 (in Chinese with English abstract)



[18]Yan W(颜伟), Wu J-Z(吴纪中), Cai S-B(蔡士宾). Identification and innovation of resistance to sharp eyespot (Rizoctonia cerealis) in wheat germplasm. Fujian Sci Technol Rice Wheat (福建稻麦科技), 2004, 22(3): 12–16 (In Chinese with English abstract)



[19]Xing X-P(邢小萍), Yuan H-X(袁虹霞), Sun B-J(孙炳剑), Li H-L(李洪连). The resistant dynamic of wheat cultivars (lines) to wheat sharp eyespot. Henan Agric Sci (河南农业科学), 2008, (12): 85–88 (in Chinese with English abstract)



[20]Shi J-R(史建荣), Wang Y-Z(王裕中), Chen H-G(陈怀谷), Shen S-W(沈素文). Screening techniques and evaluation of wheat resistance to sharp eyespot caused by Rhizoctonia cerealis. Acta Phytophalacica Sin (植物保护学报), 2000, 27(2): 107–112 (in Chinese with English abstract)



[21]Li H-L(李洪连), Yuan H-X(袁虹霞), Diao X-G(刁晓葛), Li S-P(李锁平), Hu Y-X(胡玉欣), Wang S-Z(王守正). Evaluation on the resistance of major wheat varieties in Henan province to sharp eyespot. Acta Agric Univ Henanensis (河南农业大学学报), 1998, 32(2): 107–111 (in Chinese with English abstract)



[22]Ren L-J(任丽娟), Chen P-D(陈佩度), Chen H-G(陈怀谷), Ma H-X(马鸿翔). Screening of resistance to sharp eyespot in wheat. J Plant Genet Resour (植物遗传资源学报), 2010, 11(1): 108–111 (in Chinese with English abstract)



[23]Zhang H-Y(张会云), Feng G-H(冯国华), Liu D-T(刘东涛), Liu S-L(刘世来), Wang L-H(王来花), Wang J(王静), Wang X-J(王晓军), Chen R-Z(陈荣振). Identification and utilization of resistance to sharp eyespot (Rhizoctonia cerealis) in wheat germplasm resources. Acta Agric Boreali-Occident Sin (西北农业学报), 2009, 18(1): 213–216 (in Chinese with English abstract)



[24]Leng S-F(冷苏凤), Zhang A-X(张爱香), Li W(李伟), Chen H-G(陈怀谷). Resistance of wheat cultivars to sharp eyespot in Jiangsu province. Jiangsu J Agric Sci (江苏农业学报), 2010, 26(6): 1176–1180 (in Chinese with English abstract)



[25]Yuan H-X(袁虹霞), Li H-L(李洪连), Wang S-Z(王守正), Li S-P(李锁平), Hu Y-X(胡玉欣). Identification of resistance to wheat sharp eyespot in wheat relatives. Acta Agric Boreali-Sin (华北农学报), 1998, 13(4): 26–29 (in Chinese with English abstract)



[26]Li H J, Conner R L, Murray T D. Resistance to soil-borne diseases of wheat: contributions from the wheatgrasses Thinopyrum intermedium and Th. ponticum. Can J Plant Sci, 2008, 88: 195–205



[27]Li H J, Wang X M. Thinopyrum ponticum and Th. intermedium: the promising source of resistance to fungal and viral diseases of wheat. J Genet Genomics, 2009, 36: 557–565



[28]Wang Y-Z(王裕中), Wu Z-F(吴志凤), Shi J-R(史建荣), Chen H-G(陈怀谷). Study on occurrence of wheat sharp eyespot in Jangsu and the factors influencing its development in fields. Acta Phytophyl Sin (植物保护学报), 1994, 21(2): 109–114 (in Chinese with English abstract)



[29]Fang Z(方正), Chen H-G(陈怀谷), Chen H-D(陈厚德), Wang Y-Z(王裕中). The profile and virulence of wheat sharp eyespot pathogens in Jiangsu. J Triticeae Crops (麦类作物学报), 2006, 26(1): 117–120 (in Chinese with English abstract)



[30]Chen Y(陈莹), Li W(李伟), Zhang X-X(张晓祥), Zhang B-Q(张伯桥), Yu H-S(于汉寿), Chen H-G(陈怀谷). Composition and virulence of pathogen of wheat sharp eyespot in north latitude 33° of China. J Triticeae Crop (麦类作物学报), 2009, 29(6): 1110–1114 (in Chinese with English abstract)



[31]Yan W(颜伟), Wu J-Z(吴纪中), Cai S-B(蔡士宾), Zhang X-Y(张仙义), Wu X-Y(吴小有). Analysis of combining ability of resistance to sharp eyespot in wheat. Jiangsu J Agric Sci (江苏农业科学), 2006, (6): 46–49 (in Chinese)



[32]Wang R R C, Wei J Z. Variations of two repetitive DNA sequences in several Triticeae genomes revealed by polymerase chain reaction and sequencing. Genome, 1995, 38: 1221–1229



[33]Li H J, Arterburn M, Jones S S, Murray T D. A new source of resistance to Tapesia yallundae associated with a homoeologous group 4 chromosome in Thinopyrum ponticum. Phytopathology, 2004, 94: 932–937



[34]Li H J, Arterburn M, Jones S S, Murray T D. Resistance to eyespot of wheat, caused by Tapesia yallundae, derived from Thinopyrum intermedium homoeologous group 4 chromosome. Theor Appl Genet, 2005, 111: 932–940



[35]Li H J, Cui L, Li H L, Wang X M, Murray T D, Conner R L, Wang L J, Gao X, Sun Y, Sun S C, Tang W H. Effective resources in wheat and wheat-Thinopyrum derivatives for resistance to Heterodera filipjevi in China. Crop Sci, 2012, 52: 1209–1217



[36]Cox C M, Murray T D, Jones S S. Perennial wheat germplasm lines resistant to eyespot, Cephalosporium stripe, and wheat streak mosaic. Plant Dis, 2002, 86: 1043–1048



[37]Li H J, Conner R L, Chen Q, Li H Y, Laroche A, Graf R J, Kuzyk A D. The transfer and characterization of resistance to common root rot from Thinopyrum ponticum to wheat. Genome, 2004, 47: 215–223



[38]Baley G J, Talbert L E, Martin J M, Young M J, Habernicht D K, Kushnak G D, Berg J E, Lanning S P, Bruchner P L. Agronomic and end-use qualities of Wheat streak mosaic virus resistant spring wheat. Crop Sci, 2001, 41: 1779–1784



[39]Tyler J M, Webster J A, Merkle O G. Designation of genes in wheat germplasm conferring greenbug resistance. Crop Sci, 1987, 27: 526–527



[40]Friebe B, Mukai Y, Dhaliwal H S, Martin T J, Gill B S. Identification of alien chromatin specifying resistance to wheat streak mosaic and greenbug in wheat germ plasm by C-banding and in situ hybridization. Theor Appl Genet, 1991, 81: 381–389



[41]Zhu F(朱凤), Yang R-M(杨荣明), Xu D-X(徐东祥), Tai D-L(邰德良). Reasons of heavy occurrence and control measures of rice sheath blight in Jiangsu Province in 2010. China Plant Protect (中国植保导刊), 2011, 31(9): 29–32 (in Chinese)
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