Genetic and pathological studies of blast resistance based on the differential
system have not been fully elucidated in the tropics due to the absence
of common differential varieties (DVs). The previous DVs (Yamada et
al. 1976; Kiyosawa et al. 1981; Tsunematsu et al. 2000)
have japonica type genetic backgrounds and are not so applicable
to tropical conditions. Several of the DVs have been found to have additional
genes against the blast isolates from the Philippines (Kiyosawa 1981;
Inukai 1994). Near-isogenic lines (NILs) carrying single resistance genes
in an indica type genetic background would be the most appropriate
DVs for understanding the mechanism of resistance to the blast pathogen
and to develop the differential system for use in the tropics. Mackill
and Bonman (1992) developed four NILs with the genetic background of an
indica type rice, CO39, and targeted Pi1, Piz-5,
Pi3, and Pita but the numbers and kinds of covered resistance
genes were insufficient to constitute a differential system.
NILs with CO39 genetic background were developed through a recurrent cycle
of backcrossing and selection with the 20 donor varieties targeting 14
kinds of resistance gene - Pib, Pik-s, Pik, Pik-h,
Pik-m, Pik-p, Pi1, Pi7, Pish, Pita,
Pita-2, Piz-5, Piz-t, and Pi5 (t). CO39 possess
a resistance gene, Pia, in its genetic background (Tsunematsu et
al. 2000). Backcrossing and selection from self-pollinated populations
were carried out six and eleven times, respectively, in each combination
by the second season of 2003. A total of 21 NILs were developed, and the
resistance of each was confirmed by the analysis against 20 standard blast
isolates from the Philippines. Based on the differential system (Yanoria
et al. 2000; Tsunematsu et al. 2000), Pia was found
to be incompatible with isolates B90002 and C923-49. All NILs were resistant
to isolates B90002 and C923-49. This confirmed that Pia is in the
genetic background of each NIL. Reaction patterns were the same for NILs
having the Pik alleles (Pik, Pik-h, Pik-m,
and Pik-p) and for those containing Pi1 and Pi7 (t),
genes known to be allelic with the Pik alleles (Inukai 1994). These
multi-allelic genes were not differentiated by the differential system
due to the inability of the isolates to differentiate each allele. NILs
carrying the Pish gene (such as IRBLsh-Ku/CO, IRBLsh-S/CO, IRBLsh-B/CO
and Ribs-Fu/CO from four different donors) showed moderate resistance
to 20 isolates, except for two isolates M64-1-3-9-1 and IK81-3 that showed
moderate susceptibility. Moderate reaction was typical of the Pish
gene against almost all isolates from the Philippines (Yanoria et al.
2000). Each NIL was designated as an IRBL line, and distinguished from
other NILs by a nomenclature based on the resistance gene, the first one
or two letters of the donor variety, and the recurrent parent, CO 39 (Table
1).
Six morphological traits (culm length, panicle length, panicle number,
spikelet fertility,
days to heading, and 100-seed weight) were comparable with those of CO39,
but the heading date of one NIL, IRBLz5-CA, was significantly later than
that of CO39 (data are not shown).
To evaluate the genetic backgrounds and introgression of resistance genes
from donor varieties, the graphical genotypes of the NILs were constructed
using 127 simple sequence repeats (SSR) markers. This analysis established
that the NILs had the same genomic structure as that of CO 39, with a
few variants of 66.9 to 76.3% of the indica type segments and 7.9
to 18.1% of the japonica type. These variations might be derived
from the cross of donor variety and selection process. Four NILs for Pish
and four NILs for Pik alleles revealed that japonica type
segments were introgressed into the middle region of the long arm on chromosome
1 and the terminal region of the long arm on chromosome 11 where each
gene has been mapped, respectively. Donor segments of target resistance
gene have not yet been detected in the other NILs. Additional analyses
are needed to define the introgressions using DNA markers that link tightly
or can detect directly the target gene. These materials will be used in
pathogenic differentiation and as sources of resistance for indica
type rice breeding.
Acknowledgment
This study was carried out under the IRRI-Japan Collaborative Research
Project (Phase III and IV) donated from Ministry of Agriculture, Forestry,
and Fisheries, and Ministry of Foreign Affairs of Japan.
References
Inukai, T., R.J. Nelson, R.S. Zeigler, R.S. Sarkarung, I. Takamure and
T. Kinoshita, 1994. Differentiation of pathogenic races of rice blast
fungus by using near-isogenic lines with indica genetic background.
J. Fac. Agr. Hokkaido Univ., 66(1): 27-35.
Kiyosawa, S, H. Ikehashi, H. Kato and Z.Z. Ling, 1981. Pathogenicity tests
of Philippine isolates of blast fungus using two sets of rice varieties.
Jpn. J. Breed. 31(4): 367-376.
Mackill, D.J. and J.M. Bonman, 1992. Inheritance of blast resistance in
near-isogenic lines of rice. Phytopathology 82: 746-749.
Tsunematsu, H., M.J.T. Yanoria, L.A. Ebron, N. Hayashi, I. Ando, H. Kato,
T. Imbe and G.S. Khush, 2000. Development of monogenic lines of rice for
rice blast resistance. Breed. Sci. 50: 229-234.
Yamada, M., S. Kiyosawa, T. Yamaguchi, T. Hirano, T. Kobayashi, K. Kushibuchi
and S. Watanabe, 1976. Proposal of a new method of differentiating races
of Pyricularia oryzae Cavara in Japan. Ann. Phytopathol. Soc. Jpn.
42: 216-219.
Yanoria, M.J.T., T. Imbe, H. Tsunematsu, L.A. Ebron, D. Mercado, H. Kato
and Y. Fukuta, 2000. Pathogenicity of IRRI blast isolates to rice blast
resistance genes. Poster presented at the 4th International
Rice Genetics Symposium, 22-27 October 2000, International Rice Research
Institute, Manila, Philippines.
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