[KSCI] Korea Science Citation Index Service

Development of Near-isogenic Japonica Rice Lines with Enhanced Resistance to Magnaporthe grisea

Kwon, Soon-Wook (National Institute of Crop Science, Rural Development Administration)
Cho, Young-Chan (National Institute of Crop Science, Rural Development Administration)
Kim, Yeon-Gyu (National Institute of Crop Science, Rural Development Administration)
Suh, Jung-Pil (National Institute of Crop Science, Rural Development Administration)
Jeung, Ji-Ung (National Institute of Crop Science, Rural Development Administration)
Roh, Jae-Hwan (National Institute of Crop Science, Rural Development Administration)
Lee, Sang-Kyu (Graduate School of Biotechnology and Plant Metabolism Research Center, Kyung Hee University)
Jeon, Jong-Seong (Graduate School of Biotechnology and Plant Metabolism Research Center, Kyung Hee University)
Yang, Sae-Jun (National Institute of Crop Science, Rural Development Administration)
Lee, Young-Tae (National Institute of Crop Science, Rural Development Administration)

Publication Information

Abstract

Thirteen near-isogenic lines (NILs) of japonica rice were developed via a backcross method using the recurrent parent Chucheong, which is of good eating quality but is susceptible to Magnaporthe grisea, and three blast resistant japonica donors, Seolak, Daeseong and Bongkwang. The agro-morphological traits of these NILs, such as heading date, culm length, and panicle length, were similar to those of Chucheong. In a genome-wide scan using 158 SSR markers, chromosome segments of Chucheong were identified in most polymorphic regions of the 13 NIL plants, and only a few chromosome segments were found to have been substituted by donor alleles. The genetic similarities of the 13 NILs to the recurrent parent Chucheong averaged 0.961, with a range of 0.932-0.984. Analysis of 13 major blast resistance (R) genes in these lines using specific DNA markers showed that each NIL appeared to contain some combination of the four R genes, Pib, Pii, Pik-m and Pita-2, with the first three genes being present in each line. Screening of nine M. grisea isolates revealed that one NIL M7 was resistant to all nine isolates; the remaining NILs were each resistant to between three and seven isolates, except for NIL M106, which was resistant to only two isolates. In a blast nursery experiment, all the NILs proved to be more resistant than Chucheong. These newly developed NILs have potential as commercial rice varieties because of their increased resistance to M. grisea combined with the desirable agronomic traits of Chucheong. They also provide material for studying the genetic basis of blast resistance.

Keywords

DNA Marker; Japonica; Magnaporthe grisea; Multiline; Near-isogenic Line; Resistance Gene;

Citations & Related Records

Times Cited By KSCI : 3 (Citation Analysis)
Times Cited By Web Of Science : 7 (Related Records In Web of Science)

Reference
Cited By KSCI

1	Cho, Y.I., Jiang, W., Chin, J.H., Piao, Z., Cho, Y.G., McCouch S.R., and Koh, H.J. (2007). Identification of QTLs associated with physiolosical nitrogen use efficiency in rice. Mol. Cells 23, 72-79
2	Hayashi, K., Hashimoto, N., Daigen, M., and Ashikawa, I. (2004). Development of PCR-based SNP markers for rice blast resistance genes at the Piz locus. Theor. Appl. Genet. 108, 1212-1220 DOI
3	Hayashi, K., Yoshida, H., and Ashikawa, I. (2006). Development of PCR-based allele-specific and InDel marker sets for nine rice blast resistance genes. Theor. Appl. Genet. 113, 251-260 DOI
4	Ishizaki, K., Hoshi, T., Abe, S., Sasaki, Y., Kobayashi, K., Kasaneyama, H., Matsui, T., and Azuma, S. (2005). Breeding of blast resistant isogenic lines in rice variety "Koshihikari" and evaluation of their characters. Breeding Sci. 55, 371-377 DOI ScienceOn
5	Jeon, J.S., Chen, D., Yi, G.H., Wang, G.L., and Ronald, P.C. (2003). Genetic and physical mapping of Pi5(t), a locus associated with broad-spectrum resistance to rice blast. Theor. Appl. Genet. 269, 280-289
6	Takeuchi, Y., Ebitani, T., Yamamoto, T., Sato, H., Ohta, H., Hirabayashi, H., Kato, H., Ando, I., Nemoto, H., Imbe, T., et al. (2006). Development of isogenic lines of rice cultivar Koshihikari with early and late heading by marker-assisted selection. Breeding Sci. 56, 405-413 DOI ScienceOn
7	Tsunematsu, H., Yanoria, M.J.T., Xborn, L., Hayashi, N., Ando, I., Kato, H., Imbe, T., and Khush, G.S. (2000). Development of monogenic lines of rice for blast resistance. Breeding Sci. 50, 229-234 DOI ScienceOn
8	Yi, G., Lee, S.K., Hong, Y.G., Cho, Y.C., Nam, M.H., Kim, S.C., Han, S.S., Wang, G.L., Hahn, T.R., Ronald, P.C., et al. (2004). Development of molecular markers linked to the rice blast resistance gene Pi5(t) for use in marker-assisted selection. Theor. Appl. Genet. 109, 978-985 DOI
9	Cho, Y.C., Roh, J.H., Kim, B.R., Choi, I.S., Kim, M.K., Han, S.S., Fukuta, Y., Hwang, H.G., and Kim, Y.G. (2005). Reaction of resistance genes of monogenic lines to rice blast (Magnaporthe grisea). Korean J. Breed. 37, 155-161
10	Harasawa, R., Hori, T., Ishikawa, K., Kasaneyama, H., and Hoshi, T. (2002). Rice blast control with Koshihikari multilines in Niigata Prefecture. In the Proceeding of 3rd Intl' Rice Blast Conference, 11-14 September, 2002, Tsukuba Science City, Ibaraki, Japan. pp. 61
11	Sasahara, M., and Koizumi, S. (2004). Rice blast control with Sasanishiki multilines in Miyagi Prefecture. In Rice Blast: Interaction with Rice and Control, S. Kawasaki, ed. (Dordreth: Kluwer Academic Publishers), pp. 201-207
12	Cho, Y.C., Kwon, S.W., Choi, I.S., Lee, S.K., Jeon, J.S., Oh, M.K., Roh, J.H., Hwang, H.G., Yang, S.J., and Kim, Y.G. (2007). Identification of major blast resistance genes in Korean rice varieties (Oryza sativa L.) using molecular markers. J. Crop Sci. Biotech. 10, 223-234
13	Qu, S., Liu, G., Zhou, B., Bellizzi, M., Zeng, L., Dai, L., Han, B., and Wang, G. (2006). The broad-spectrum blast resistance gene Pi9 encodes an NBS-LRR protein and is a member of a multigene family in rice. Genetics 172, 1901-1914 DOI ScienceOn
14	Bonman, J.M., Vergel, de Dios T.I., and Khin, M.M. (1986). Physiologic specialization of Pyricularia oryzae in the Philippines. Plant Disease 70, 767-769 DOI
15	Borlaug, N.E. (1959). The use of multilineal or composite varieties to control airborne epidemic diseases of self-pollinated crop plants. In Proc. 1st Intl' Wheat Genet. Symp., Winnipeg, pp. 12-26
16	Liu, G., Lu, G., Zeng, L., and Wang, G.L. (2002). Two broadspectrum blast resistance genes, Pi9(t) and Pi2(t), are physically linked on rice chromosome. Mol. Genet. Genomics 267, 472-480 DOI
17	Jia, Y., Wang, Z., Fjellstrom, R.G., Moldenhauer, K.A.K., Azam, M.D.A., Correll, J., Lee, F.N., Xia, Y., and Rutger, J.N. (2004). Rice Pi-ta gene confers resistance to the major pathotypes of the rice balst fungus in the United States. Phytopathology 94, 296-301 DOI ScienceOn
18	Rohlf, F.J. (1998). NTSYS-pc: numerical taxonomy and multivariate analysis system. Version 2.11L [computer program]. Exeter Software, Setauket, N.Y., USA
19	Yaegashi, H. (1994). Use of resistant varieties and disease control for paddy rice. Agric. Hortic. 69, 149-154
20	Yamanaka, S., and Yamaguchi, T. (1987). Rice Blast Disease (Yokendo, Tokyo: Japan), (in Japanese)
21	Choi, J.E., Park, J.S., and Park, N.K. (1989). Resistance of varieties to rice blast in Korea I. Japonica type of rice varieties. J. Agri. Sci. Chungnam Natl' Univ., Korea Vol. 16, 1-18 (English summary)
22	Nakajima, T., Sonoda, R., and Yaegashi, H. (1996). Effect of a multiline of rice cultivar Sasanishiki and its isogenic lines on supressing rice blast disease. Ann. Phytopathology Soc. Japan 62, 227-233 DOI ScienceOn
23	Koizumi, S., Ashizawa, T., and Zenbayashi, K. (2004). Durable control of rice blast disease with multilines. In Rice Blast: Interaction with Rice and Control, S. Kawasaki, ed. (Dordreth: Kluwer Academic Publishers), pp. 191-199
24	Jia, Y., Wang, Z., and Shing, P. (2002). Development of dominant rice blast Pi-ta resistance gene markers. Crop Sci. 42, 2145-2149 DOI ScienceOn
25	Kojima, Y., Ebitani, T., Yamamoto, Y., and Nagamine, T. (2004). Development and utilization of isogenic lines Koshihikari Toyama BL. In Rice Blast: Interaction with Rice and Control, S. Kawasaki, ed. (Dordreth: Kluwer Academic Publishers), pp. 209-214
26	Paterson, A.H., DeVerna, J.W., Lanini, B., and Tanksley, S.D. (1990). Fine mapping of quantitative trait loci using selected overlapping recombinant chromosomes in an interspecies cross of tomato. Genetics 124, 735-742
27	Koizumi, S., and Tani, T. (2000). Effective control of rice blast disease with "Sasanishiki" multiline.: In Advances in Rice Blast Research, D. Tharreau et al., eds. (The Netherlands: Kluwer Academic Publishers), pp. 137-145
28	Choi, H.C., Kim, Y.G., Hong, H.C., Moon, H.P., Ahn, S.N., Hwang, H.G., Song, M.T., Yang, S.J., Kim, H.Y., Han, S.S., et al. (2000). A new high-quality and blast resistance multiline of rice "Saechucheongbyeo". Treat. of Crop Res. 1, 49-57
29	Lee, J.S. (2003). QTL analysis for grain quality properties in a japonica rice combination. Ph. D. Thesis, Yeungnam Univ., Korea, p. 64

1	Analysis of Korean japonica rice cultivars using molecular markers associated with blast resistance genes / [Suh, Jung-Pil;Roh, Jae-Hwan;Cho, Young-Chan;Han, Seong-Sook;Jeon, Yong-Hee;Kang, Kyung-Ho;Kim, Yeon-Gyu;] / Korean Journal of Breeding Science
2	Screening of the Dominant Rice Blast Resistance Genes with PCR-based SNP and CAPS Marker in Aromatic Rice Germplasm / [Kim, Jeong-Soon;Ahn, Sang-Nag;Hong, Sung-Jun;Kwon, Jin-Hyeuk;Kim, Yeong-Ki;Jee, Hyeong-Jin;Shim, Chang-Ki;] / KOREAN JOURNAL OF CROP SCIENCE
3	Identification of Quantitative Trait Loci Associated with Rice Eating Quality Traits Using a Population of Recombinant Inbred Lines Derived from a Cross between Two Temperate japonica Cultivars / [Kwon, Soon-Wook;Cho, Young-Chan;Lee, Jeong-Heui;Suh, Jung-Pil;Kim, Jeong-Ju;Kim, Myeong-Ki;Choi, Im-Soo;Hwang, Hung-Goo;Koh, Hee-Jong;Kim, Yeon-Gyu;] / Molecules and Cells