Functional complementation of rice blast resistance gene Pi-k h (Pi54) conferring resistance to diverse strains of Magnaporthe oryzae

Blast disease of rice, caused by Magnaporthe oryzae is an explosive disease that can spread rapidly in conducive conditions. R-gene mediated resistance offers an environmentally sustainable solution for management of this important disease of rice. We have earlier identified a unique R-gene of rice, on chromosome 11 of Oryza sativa ssp. indica cultivar Tetep. In this study we report functional validation of the Pi-k ^h (Pi54) gene using complementation assay. The blast resistance candidate gene Pi-k ^h (Pi54) was cloned into a plant transformation vector and the construct was used to transform a japonica cultivar of rice Taipei 309, which is susceptible to M. oryzae. Transgenic lines containing Pi-k ^h (Pi54) gene were found to confer high degree of resistance to diverse isolates of M. oryzae. The callose deposition was analyzed and compared between the transgenic and non-transgenic rice plants and widespread deposition was observed at the infection sites in plants showing incompatible interaction. Successful complementation of Pi-k ^h (Pi54) gene confirmed that the gene is responsible for resistance to M. oryzae in transgenic lines developed during this study. Expression analysis of the gene in resistant plants revealed that the gene is pathogen inducible in nature and is not expressed constitutively. Detection of callose deposition in resistant plants containing Pi-k ^h (Pi54) gene implicates its involvement in the initiation of defense response cascade.     

Development of PCR-based allele-specific and InDel marker sets for nine rice blast resistance genes

Blast resistance is one of the most important traits in rice breeding, and application of molecular markers for blast resistance breeding is likely to allow the rapid screening for the trait during early growth stages, without the need for inoculation of pathogen and phenotyping. Allele-specific PCR markers and insertion/deletion (InDel) markers, which genotype single-nucleotide polymorphisms and InDel polymorphisms, respectively, are useful tools for marker-assisted selections. We developed sets of allele-specific PCR and InDel markers for nine rice blast resistance genes—Piz, Piz-t, Pit, Pik, Pik-m, Pik-p, Pita, Pita-2, and Pib—which are commonly used in Japanese blast resistance rice breeding programs. For each resistance gene, we used the segregation information from thousands of progeny in several crosses or published gene locations to generate a marker that cosegregated with the gene and markers that closely flanked the gene on either side. The developed cosegregating markers uniquely discriminated among each of the lines with the individual resistance genes (except for Pita and Pita-2). Therefore, these markers will likely facilitate the development of multiline cultivars carrying one or a combination of these nine blast resistance genes. In addition, the systems we developed may be valuable tools in the quality control of seed production from blast-resistant multiline cultivars.     

Characterization of the rice blast resistance gene Pik cloned from Kanto51

To study similar, but distinct, plant disease resistance (R) specificities exhibited by allelic genes at the rice blast resistance locus Pik/Pikm, we cloned the Pik gene from rice cultivar Kanto51 and compared its molecular features with those of Pikm and of another Pik gene cloned from cv. Kusabue. Like Pikm, Pik is composed of two adjacent NBS-LRR (nucleotide-binding site, leucine-rich repeat) genes: the first gene, Pik1-KA, and the second gene, Pik2-KA. Pik from Kanto51 and Pik from Kusabue were not identical; although the predicted protein sequences of the second genes were identical, the sequences differed by three amino acids within the NBS domain of the first genes. The Pik proteins from Kanto51 and Kusabue differed from Pikm in eight and seven amino acids, respectively. Most of these substituted amino acids were within the coiled-coil (CC) and NBS domains encoded by the first gene. Of these substitutions, all within the CC domain were conserved between the two Pik proteins, whereas all within the NBS domain differed between them. Comparison of the two Pik proteins and Pikm suggests the importance of the CC domain in determining the resistance specificities of Pik and Pikm. This feature contrasts with that of most allelic or homologous NBS-LRR genes characterized to date, in which the major specificity determinant is believed to lie in the highly diverged LRR domain. In addition, our study revealed high evolutionary flexibility in the genome at the Pik locus, which may be relevant to the generation of new R specificities at this locus.     

The isolation of Pi1, an allele at the Pik locus which confers broad spectrum resistance to rice blast

We report the isolation of Pi1, a gene conferring broad-spectrum resistance to rice blast (Magnaporthe oryzae). Using loss- and gain-of-function approaches, we demonstrate that Pi1 is an allele at the Pik locus. Like other alleles at this locus, Pi1 consists of two genes. A functional nucleotide polymorphism (FNP) was identified that allows differentiation of Pi1 from other Pik alleles and other non-Pik genes. A extensive germplasm survey using this FNP reveals that Pi1 is a rare allele in germplasm collections and one that has conferred durable resistance to a broad spectrum of pathogen isolates.     

The isolation and characterization of Pik, a rice blast resistance gene which emerged after rice domestication

? The rice-rice blast pathosystem is of great interest, not only because of the damaging potential of rice blast to the rice crop, but also because both the pathogen and its host are experimentally amenable. The rice blast resistance gene Pik, which is one of the five classical alleles located at the Pik locus on the long arm of chromosome 11, confers high and stable resistance to many Chinese rice blast isolates. ? The isolation and functional characterization of Pik were performed in the present study through genetic and genomic approaches. ? A combination of Pik-1 and Pik-2 is required for the expression of Pik resistance. Both Pik-1 and Pik-2 encode coiled-coil nucleotide binding site leucine-rich repeat (NBS-LRR) proteins, and each shares a very high level of protein identity with corresponding proteins encoded by the Pik-m and Pik-p alleles. Pik could be distinguished from other Pik alleles, including Pik-m and Pik-p, by the allele-specific, single-nucleotide polymorphism T1-2944G. ? The coupled genes probably did not evolve as a result of a duplication event, and are far from any NBS-LRR R gene characterized. Pik is a younger allele at the locus that probably emerged after rice domestication.     

Saturation mapping with subclones of YACs: DNA marker production targeting the rice blast disease resistance gene, Pi-b

Saturation mapping of a very small genomic region is indispensable for map-based cloning. We applied a method based on sub-cloning and the Southern-hybridization technique for generating RFLP markers directly from yeast artificial chromosomes (YACs). Two YACs overlapping each other and covering the locus of the rice blast resistance gene, Pi-b, were used to construct a plasmid sub-library. Rice-specific and single-copy clones suitable as probes for RFLP analysis were selected from this sub-library by hybridization to the blots of digested DNAs of rice, YACs, and yeast. As a result, 22 markers were produced within a small chromosomal region including Pi-b. This case study shows that overlapping YACs known to cover the gene of interest are very useful in fine-scale physical mapping leading to map-based cloning of the target gene. Received: 2 May 1996 / Accepted: 2 August 1996     

Development and validation of a PCR-based functional marker system for the major wide-compatible gene locus S5 in rice

The major wide-compatibility gene locus S5 in rice (Oryza sativa L.) located on chromosome 6 has been recently cloned and a 136-bp deletion in the candidate gene encoding aspartyl protease has been characterized to be specific for wide-compatible varieties, while many single nucleotide polymorphisms have been identified at S5 between indica and japonica rice types. In the present study, we designed a PCR-based multiplex functional marker system targeting the deletion and the SNPs for precise determination of the allelic status at S5. By deploying the marker system, the allelic status at the S5 locus in 584 rice genotypes has been assayed. A total of 116 genotypes, including 11 cultivars, two known wide-compatible varieties, 48 IRRI germplasm lines, 12 Indian aromatic rice genotypes, 37 restorer lines and six breeding lines, have been identified to possess the 136-bp deletion specific for the neutral allele at S5. The marker system was able to clearly distinguish indica and japonica alleles from the neutral allele and has been validated in a mapping population derived from the three-way cross IR36/Dular//Akihikari, which segregated for spikelet sterility/fertility. The functional marker system targeting S5 developed in the present study will be very useful in rapid identification of wide-compatible genotypes, in predicting the success of inter-subspecific crosses and in targeted introgression of the wide-compatible allele of S5 into elite indica and japonica rice varieties.     

Improving blast resistance of maintainer line DRR 9B by transferring broad spectrum resistance gene Pi2 by marker assisted selection in rice

Hybrid rice technology offers great promise to further enhance rice production and productivity for global food security. Improving hybrid rice parental lines is the first step in developing heterotic rice hybrids. To improve resistance against blast disease, a maintainer line DRR 9B was fortified with a major broad-spectrum blast resistance gene Pi2 through marker-assisted selection. The rice blast caused by Magnaporthe oryzae is a major disease and can cause severe yield losses upto 100%. The NILs of Samba Mahsuri namely BA-23-11-89-12-168 possessing Pi2 was utilized as a donor parent. The PCR-based molecular marker tightly linked to Pi2 gene was used for the foreground selection at BC₁F₁ generation. The molecular marker tightly linked to the major fertility restorer gene Rf4 was used for negative selection (i.e., selection of plants possessing non fertility restoring alleles) at BC₁F₁ generation to identify maintainer lines. The positive plants with Rf4 gene were added to the restorer pool for restorer line development. At each stage, MAS for Pi2 coupled with stringent phenotypic selection for agro-morphological and grain quality traits were exercised. At BC₁F₃ generation, one hundred families were screened against blast disease at uniform blast nursery (UBN) and selected resistant lines were advanced to next generations. In the BC₁F₅ generation plants were subjected to agro-morphological evaluation for yield and yield-contributing traits. The selected plants at BC₁F₅ generation were crossed with DRR 9A to assess the maintainer ability of blast resistance lines and for further CMS line conversion for hybrid rice breeding for developing blast resistance rice hybrids.     

Identification of the blast resistance gene Pit in rice cultivars using functional markers

DNA markers that allow for identification of resistance genes in rice germplasm have a great advantage in resistance breeding because they can assess the existence of the genes without laborious inoculation tests. Functional markers (FMs), which are designed from functional polymorphisms within the sequence of genes, are unaffected by nonfunctional allelic variation and make it possible to identify an individual gene. We previously showed that the resistance function of the rice blast resistance gene Pit in a resistant cultivar, K59, was mainly acquired by up-regulated promoter activity through the insertion of a long terminal repeat (LTR) retrotransposon upstream of Pit. Here, we developed PCR-based DNA markers derived from the LTR-retrotransposon sequence and used these markers to screen worldwide accessions of rice germplasm. We identified 5 cultivars with the LTR-retrotransposon insertion out of 68 rice accessions. The sequence and expression pattern of Pit in the five cultivars were the same as those in K59 and all showed Pit-mediated blast resistance. The results suggest that the functional Pit identified using the markers was derived from a common progenitor. Additionally, comparison of the Pit coding sequences between K59 and susceptible cultivars revealed that one nucleotide polymorphism, which caused an amino acid substitution, offered another target for a FM. These results indicate that our DNA markers should enhance prediction of Pit function and be applicable to a range of rice varieties/landraces cultivated in various regions worldwide and belonging to the temperate japonica, tropical japonica, and indica groups.     

Regions outside the leucine-rich repeat domain determine the distinct resistance specificities of the rice blast resistance genes Pik and Pik-m

Two alleles of the rice blast resistance (R) Pik locus, Pik-m and Pik, are each composed of a pair of nucleotide-binding site–leucine-rich repeat (NBS–LRR) genes, referred to as the first gene and the second gene. Pik-m and Pik are unique in that many of the amino acid substitutions between them are distributed in or near the N-terminal coiled-coil (CC) domain of the first gene, suggesting that the CC domain of the first gene plays an important role in determinating their R specificity. To examine this hypothesis, I investigated resistance phenotypes of transgenic plants carrying each of two kinds of domain-swapped Pik-m-based recombinant first genes. Replacement of the LRR domain of Pik-m with the equivalent region of Pik did not change the Pik-m-type specificity, indicating that regions outside the LRR domain are responsible for differentiating the R specificity of Pik-m from Pik. In contrast, replacement of both the NBS and LRR domains of Pik-m with the corresponding region of Pik resulted in loss of blast resistance, suggesting that co-adaptation of polymorphisms in the CC and NBS domains is necessary to maintain resistance.     

Identification of RAPD markers linked to a major blast resistance gene in rice

Rice blast, caused byPyricularia grisea, is a major production constraint in many parts of the world. The Korean rice variety Tongil showed high levels of resistance for about six years when widely planted under highly disease-conducive conditions, before becoming susceptible. Tongil was found to carry a single dominant gene, designatedPi-10t, conferring resistance to isolate 106 of the blast pathogen from the Philippines. We report here the use of bulked segregant RAPD analysis for rapid identification of DNA markers linked toPi-10t. Pooled DNA extracts from five homozygous blast-resistant (RR) and five susceptible (rr) BC₃F₂ plants, derived from a CO39 × Tongil cross, were analyzed by RFLP using 83 polymorphic probes and by RAPD using 468 random oligomers. We identified two RAPD markers linked to thePi-10t locus: RRF6 (3.8 ± 1.2 cM) and RRH18 (2.9 ± 0.9 cM). Linkage of these markers withPi-10t was verified using an F2 population segregating forPi-10t. The two linked RAPD markers mapped 7 cM apart on chromosome 5. Chromosomal regions surrounding thePi-10t gene were examined with additional RFLP markers to define the segment introgressed from the donor genome.Pi-10t is likely to be a new blast-resistance locus, because no other known resistance gene has been mapped on chromosome 5. These tightly linked RAPD markers could facilitate early selection of thePi-10t locus in rice breeding programmes.     

Pi35(t), a new gene conferring partial resistance to leaf blast in the rice cultivar Hokkai 188

The japonica rice cultivar Hokkai 188 shows a high level of partial resistance to leaf blast. For mapping genes conferring the resistance, a set of 190 F₂ progeny/F₃ families was developed from the cross between the indica rice cultivar Danghang-Shali, with a low level of partial resistance, and Hokkai 188. Partial resistance to leaf blast in the F₃ families was assessed in upland nurseries. From a primary microsatellite (SSR) linkage map and QTL analysis using a subset of 126 F₂ progeny/F₃ families randomly selected from the above set, one major QTL located on chromosome 1 was detected in the vicinity of SSR marker RM1216. This QTL was responsible for 69.4% of the phenotypic variation, and Hokkai 188 contributed the resistance allele. Segregation analysis in the F₃ families for partial resistance to leaf blast was in agreement with the existence of a major gene, and the gene was designated as Pi35(t). Another QTL detected on chromosome 8 was minor, explained 13.4% of the phenotypic variation, and an allele of Danghang-Shali increased the level of resistance in this QTL. Additional SSR markers of the targeted Pi35(t) region were further surveyed in the 190 F₂ plants, and Pi35(t) was placed in a 3.5-cM interval flanked by markers RM1216 and RM1003.     

Development and validation of co-dominant gene based markers for <Emphasis Type="Italic">Pi9</Emphasis>, a gene governing broad-spectrum resistance against blast disease in rice

Rice production and grain quality are severely affected by blast disease caused by the ascomycetous fungus Magnaporthe oryzae. Incorporation of genes that confer broad-spectrum resistance to blast has been a priority area in rice breeding programs. The blast resistance gene Pi9 sourced from Oryza minuta has shown broad spectrum and durable resistance to blast world-wide. In the present study co-dominant gene-based markers were developed for the precise marker-assisted tracking of Pi9 in breeding programs. The developed markers were validated across a diverse set of cultivars including basmati, indica and japonica varieties. Two markers, Pi9STS-1 and Pi9STS-2, effectively differentiated Pi9 donors from all the indicas and commercial basmati varieties tested. However, these markers were monomorphic between Pi-9 donors (IRBL9-W and Pusa 1637) and japonica type varieties. An additional gene-derived CAPS marker Pi91F_ 2R was developed to differentiate Pi9 donors from japonicas and traditional basmati lines. The co-dominant markers developed in the present study will be of immense utility to rice breeders for precise and speedy incorporation of Pi-9 into susceptible rice varieties through marker-assisted selection.     

Development of a PCR-based marker to identify rice blast resistance gene,Pi-2(t), in a segregating population

The genomic clone RG64, which is tightly linked to the blast resistance gene Pi-2(t) in rice, provides means to perform marker-aided selection in a rice breeding program. The objective of this study was to investigate the possibility of generating a polymerase chain reaction (PCR)-based polymorphic marker that can distinguish the blast resistant gene, Pi-2(t), and susceptible genotypes within cultivated rice. RG64 was sequenced, and the sequence data was used to design pairs of specific primers for (PCR) amplification of genomic DNA from rice varieties differing in their blast disease responsiveness. The amplified products, known as sequenced-tagged-sites (STSs), were not polymorphic between the three varieties examined. However, cleavage of the amplified products with the restriction enzyme HaeIII generated a polymorphic fragment, known as specific amplicon polymorphism (SAP), between the resistant and the susceptible genotypes. To examine the power of the identified SAP marker in predicting the genotype of the Pi-2 (t) locus, we determined the genotypes of the F₂ individuals at this locus by performing progeny testing for the disease response in the F₃ generation. The results indicated an accuracy of more than 95% in identifying the resistant plants, which was similar to that using RG64 as the hybridization probe. The identification of the resistant homozygous plants increased to 100% when the markers flanking the genes were considered simultaneously. These results demonstrate the utility of SAP markers as simple and yet reliable landmarks for use in marker-assisted selection and breeding within cultivated rice.