Identification of resistant germplasm containing novel resistance genes at or tightly linked to the Pi2/9 locus conferring broad-spectrum resistance against rice blast

Gui Xiao; Frances Nikki Borja; Ramil Mauleon; Jonas Padilla; Mary Jeanie Telebanco-Yanoria; Jianxia Yang; Guodong Lu; Maribel Dionisio-Sese; Bo Zhou

doi:10.1186/s12284-017-0176-z

Identification of resistant germplasm containing novel resistance genes at or tightly linked to the Pi2/9 locus conferring broad-spectrum resistance against rice blast

Rice (N Y). 2017 Dec;10(1):37. doi: 10.1186/s12284-017-0176-z. Epub 2017 Aug 4.

Authors

Gui Xiao^{1

2}, Frances Nikki Borja¹, Ramil Mauleon¹, Jonas Padilla¹, Mary Jeanie Telebanco-Yanoria¹, Jianxia Yang³, Guodong Lu³, Maribel Dionisio-Sese², Bo Zhou⁴

Affiliations

¹ Genetics and Biotechnology Division, International Rice Research Institute, DAPO Box 7777, Metro Manila, Philippines.
² Institute of Biological Sciences, University of the Philippines Los Baños, 4031, Laguna, Philippines.
³ Fujian Agriculture and Forest University, Fuzhou, 350002, China.
⁴ Genetics and Biotechnology Division, International Rice Research Institute, DAPO Box 7777, Metro Manila, Philippines. b.zhou@irri.org.

Abstract

Background: The rice Pi2/9 locus harbors multiple resistance (R) genes each controlling broad-spectrum resistance against diverse isolates of Magnaporthe oryzae, a fungal pathogen causing devastating blast disease to rice. Identification of more resistance germplasm containing novel R genes at or tightly linked to the Pi2/9 locus would promote breeding of resistance rice cultivars.

Results: In this study, we aim to identify resistant germplasm containing novel R genes at or tightly linked to the Pi2/9 locus using a molecular marker, designated as Pi2/9-RH (Pi2/9 resistant haplotype), developed from the 5' portion of the Pi2 sequence which was conserved only in the rice lines containing functional Pi2/9 alleles. DNA analysis using Pi2/9-RH identified 24 positive lines in 55 shortlisted landraces which showed resistance to 4 rice blast isolates. Analysis of partial sequences of the full-length cDNAs of Pi2/9 homologues resulted in the clustering of these 24 lines into 5 haplotypes each containing different Pi2/9 homologues which were designated as Pi2/9-A5, -A15, -A42, -A53, and -A54. Interestingly, Pi2/9-A5 and Pi2/9-A54 are identical to Piz-t and Pi2, respectively. To validate the association of other three novel Pi2/9 homologues with the blast resistance, monogenic lines at BC₃F₃ generation were generated by marker assisted backcrossing (MABC). Resistance assessment of the derived monogenic lines in both the greenhouse and the field hotspot indicated that they all controlled broad-spectrum resistance against rice blast. Moreover, genetic analysis revealed that the blast resistance of these three monogenic lines was co-segregated with Pi2/9-RH, suggesting that the Pi2/9 locus or tightly linked loci could be responsible for the resistance.

Conclusion: The newly developed marker Pi2/9-RH could be used as a potentially diagnostic marker for the quick identification of resistant donors containing functional Pi2/9 alleles or unknown linked R genes. The three new monogenic lines containing the Pi2/9 introgression segment could be used as valuable materials for disease assessment and resistance donors in breeding program.

Keywords: Magnaporthe oryzae; Pi2/9 homologues; Resistant haplotype specific marker.