Genetic analysis of leaffolder resistance in rice

Yuchun Rao; Guojun Dong; Dali Zeng; Jiang Hu; Longjun Zeng; Zhengyu Gao; Guanghen Zhang; Longbiao Guo; Qian Qian

doi:10.1016/S1673-8527(09)60050-3

Volume 37 Issue 5

May 2010

Turn off MathJax

Article Contents

Article Navigation > Journal of Genetics and Genomics > 2010 > 37(5): 325-331

PDF( 310 KB)

Genetic analysis of leaffolder resistance in rice

doi: 10.1016/S1673-8527(09)60050-3

a
State Key Laboratory of Rice Biology, China National Rice Research Institute, Hangzhou 310006, China
b
Graduate School of Chinese Academy of Agriculture Science, Beijing 100081, China

More Information

Corresponding author: E-mail address: qianqian188@hotmail.com (Dali Zeng); E-mail address: dalizeng@126.com (Qian Qian)
Received Date: 2009-09-10
Accepted Date: 2010-03-17
Rev Recd Date: 2010-02-03

Available Online: 2010-05-31

Publish Date: 2010-05-20

Abstract

Abstract

A double haploid (DH) population, which consists of 120 lines derived from anther culture of a typical indica and japonica hybrid ‘CJ06’/‘TN1’, was used to investigate the genetic basis for rice leaffolder resistance. Using a constructed molecular linkage map, five QTLs for rolled leaves were detected on chromosomes 1, 2, 3, 4, and 8. The positive alleles from CJ06 on chromosomes 3, 4, and 8 increased the resistance to rice leaffolder, and the alleles from TN1 on chromosomes 1 and 2 also enhanced resistance to leaffolder. The interactions between QTLs were identified and tested, and four conditional interactions were acquired for resistance to rice leaffolder. These loci were located on chromosomes 2, 9, 10, and 11, respectively. QTL pyramiding indicated that the positive alleles affect resistance to leaffolder. The prospective application of this data in rice breeding was also discussed.
- rice (Oryza sativa L.),
- rice leaffolder,
- QTL analysis,
- conditional interaction

These authors contributed equally to this work.

FullText(HTML)

References(35)

References

[1]	Alam, S.N., Cohen, M.B. Detection and analysis of QTL for resistance to the brown planthopper in a double-haploid rice population Theor. Appl. Genet., 97 (1998),pp. 1370-1379
[2]	Khurram, B., Tayyab, H., Tahira, F. et al. Mol. Breeding, 13 (2004),pp. 301-312
[3]	Bautista, R.C., Heinrichs, E.A., Rejesus, R.S. Environ. Entomol., 13 (1984),pp. 439-443
[4]	Chase, K., Adler, F.R., Lark, K.G. Epistat: a computer program for identifying and testing interaction between pairs of quantitative loci Theor. Appl. Genet., 94 (1997),pp. 724-730
[5]	Chen, S.H., Zhuang, J.Y., Cao, L.Y. et al. Molecular breeding for super rice hybrids Chinese Journal of Rice Science, 18 (2004),pp. 377-383
[6]	Dhakshayani, K., Bentur, J.S., Kalode, M.B. Insect Sci. Appl., 14 (1993),pp. 107-114
[7]	Food and Agriculture Organization of the United Nations (FAO) FAO Quarterly Bulletin of Statistics, 18 (1995),pp. 1-2
[8]	Food and Agriculture Organization of the United Nations (FAO). (2004). The State of Food Security in The World. pp. 30–31.
[9]	Gottfried, F., Faheemah, F. Entomologia Experimentalis et Applicata, 29 (1981),pp. 138-146
[10]	He, P., Li, S.G., Qian, Q. et al. Genetic analysis of rice grain quality Theor. Appl. Genet., 98 (1999),pp. 502-508
[11]	Heinrichs, E.A., Medrano, F.G., Rapusas, H.R.
[12]	Heong, K.L., Teng, P.S., Moody, K. Managing rice pests with less chemicals GeoJournal, 35 (1995),pp. 337-349
[13]	Hu, X.M., Guo, L.B., Zeng, D.L. et al. QTL mapping and epistasis analysis of rice root growth ability at seedling stage Chinese Journal of Rice Science, 18 (2004),pp. 396-400
[14]	Khush, G.S., and Brar, D.S. (2002). Biotechnology for rice breeding: Progress and potential impact. In: Proceeding of the 20th Session of the International Rice Commission.
[15]	Li, D.H., Fu, Q., Wang, F. et al. Chinese Journal of Rice Science, 18 (2004),pp. 43-47
[16]	Lincoln, S., Daly, M., Lander, E.
[17]	Lu, C.F., Shen, L.S., Tan, Z.B. et al. Comparative mapping of QTLs for agronomic traits of rice across environments using a doubled haploid population Theor. Appl. Genet., 93 (1996),pp. 1211-1217
[18]	Luo, W., Hu, J., Sun, C. et al. Genetic analysis of related phenotypes of functional leaf in rice heading stage Mol Plant Breed, 6 (2008),pp. 853-860
[19]	McCouch, S.R., Cho, Y.G., Yano, M. et al. Report on QTL nomenclature Rice Genet. Newsl., 14 (1997),pp. 111-131
[20]	Peng, S., Tang, Q., Zou, Y. Current status and challenges of rice production in China Plant Production Science, 12 (2009),pp. 3-8
[21]	Rong, J., Song, Z.P., Su, J. et al. Biodiversity Sci., 14 (2006),pp. 309-314
[22]	Rothschild, G., (1996). Rice Genetics III Edited by GS Khush IRRI pp. 1–2.
[23]	Sardesai, N., Rajyashri, K.R., Behura, S.K. et al. Genetic, physiological and molecular interactions of rice with its major dipteran pest, gall midge Plant Cell Tissue Organ. Cult., 64 (2001),pp. 115-131
[24]	Selvaraju, K., Shanmugasundaram, P., Mohankumar, S. et al. Euphytica, 157 (2007),pp. 35-43
[25]	Sogawa, K., Qian, Q., Zeng, D.L. et al. Differential expression of whitebacked planthopper resistance in the japonica/indica doubled haploid rice population under field evaluation and seedbox screening test Rice Sci., 12 (2005),pp. 63-67
[26]	Song, X.L., Qiang, S., Liu, L.L. et al. Journal of Nanjing Agriculture University, 25 (2002),pp. 5-8
[27]	Wang, Y.H., Li, J.Y. Plant Mol. Biol., 59 (2005),pp. 75-84
[28]	Wu, T., Jiang, W.H. Analysis and management strategies of outbreak for rice leaf roller in 2003 HuBei Plant Protection, 2 (2004),pp. 18-19
[29]	Wu, W.R., Tang, D.Z., Li, W.M. Genetic dissection and molecular dissection of quantitative traits Acta Agronomica Sinica, 26 (2000),pp. 501-507
[30]	Xu, Y.B., Shen, L.S., McCouch, S.R. et al. Extension of the rice DH population genetic map with microsatellite markers Chin Sci. Bull., 42 (1998),pp. 149-152
[31]	Xu, S.Z., Zeng, Y.J. Effect of the main pest to yield in rice JiangXi Plant Protection, 26 (2003),pp. 15-17
[32]	Xiong, Z.M.
[33]	Xiao, M.K. Preliminary study on relationship between leaf sheath rotted disease and rice leaf roller Plant Protection, 16 (1990),p. 29
[34]	Yang, Z.X., Jiang, G.H., Xu, C.G. et al. Simultaneously improvement of resistance to bacterial blight and stem borer of 9311 by molecular marker-assisted selection Mol. Plant Breed, 2 (2004),pp. 473-480
[35]	Zeng, D.L., Qian, Q., Ruan, L.Q. et al. QTL analysis of chalkiness size in three dimensions Chinese Journal of Rice Science, 16 (2002),pp. 11-14