SSRs for Marker-Assisted Selection for Blast Resistance in Rice (Oryza sativa L.)

Rice blast caused by the fungus Magnaporthe oryzae is one of the most devastating diseases of rice in nearly all rice growing areas of the world including Malaysia. To develop cultivars with resistance against different races of M. oryzae, availability of molecular markers along with marker-assisted selection strategies are essential. In this study, 11 polymorphic simple sequence repeat (SSR) markers with good fit of 1:2:1 ratio for single gene model in F₂ population derived from the cross of Pongsu seribu 2 (Resistant) and Mahsuri (Susceptible) rice cultivars were analysed in 296 F₃ families derived from individual F₂ plants to investigate association with Pi gene conferring resistance to M. oryzae pathotype. Parents and progeny were grouped into two phenotypic classes based on their blast reactions. Chi-square test for the segregation of resistance and susceptibility in F₃ generation fitted a ratio of approximately 3:1. Association of SSR markers with phenotypic trait in F₃ families was identified by statistical analysis. Four SSR markers (RM413, RM5961, RM1233 and RM8225) were significantly associated with blast resistance to pathotype 7.2 of M. oryzae in rice (p ≤ 0.01). These four markers accounted for about 20% of total phenotypic variation. So, these markers were confirmed as suitable markers for use in marker-assisted selection and confirmation of blast resistance genes to develop rice cultivars with durable blast resistance in Malaysian rice breeding programmes.     

Pigment and Virulence Deficiencies Associated with Mutations in the aroE Gene of Xanthomonas oryzae pv. oryzae

Xanthomonadins are yellow, membrane-bound pigments produced by members of the genus Xanthomonas. We identified an ethyl methanesulfonate-induced Xanthomonas oryzae pv. oryzae mutant (BXO65) that is deficient for xanthomonadin production and virulence on rice, as well as auxotrophic for aromatic amino acids (Pig⁻ Vir⁻ Aro⁻). Reversion analysis indicated that these multiple phenotypes are due to a single mutation. A genomic library of the wild-type strain was used to isolate a 7.0-kb clone that complements BXO65. By transposon mutagenesis, marker exchange, sequence analysis, and subcloning, the complementing activity was localized to a 849-bp open reading frame (ORF). This ORF is homologous to the aroE gene, which encodes shikimate dehydrogenase in various bacterial species. Shikimate dehydrogenase activity was present in the wild-type strain and the mutant with the complementing clone, whereas no activity was found in BXO65. This clone also complemented an Escherichia coli aroE mutant for prototrophy, indicating that aroE is functionally conserved in X. oryzae pv. oryzae and E. coli. The nucleotide sequence of the 2.9-kb region containing aroE revealed that a putative DNA helicase gene is located adjacent to aroE. Our results indicate that aroE is required for normal levels of virulence and xanthomonadin production in X. oryzae pv. oryzae.     

Characterization of a novel plant growth-promoting bacteria strain Delftia tsuruhatensis HR4 both as a diazotroph and a potential biocontrol agent against various plant pathogens

A novel, plant growth-promoting bacterium Delftia tsuruhatensis, strain HR4, was isolated from the rhizoplane of rice (Oryza sativa L., cv. Yueguang) in North China. In vitro antagonistic assay showed this strain could suppress the growth of various plant pathogens effectively, especially the three main rice pathogens (Xanthomonas oryzae pv. oryzae, Rhizoctonia solani and Pyricularia oryzae Cavara). Treated with strain HR4 culture, rice blast, rice bacterial blight and rice sheath blight for cv. Yuefu and cv. Nonghu 6 were evidently controlled in the greenhouse. Strain HR4 also showed a high nitrogen-fixing activity in N-free Döbereiner culture medium. The acetylene reduction activity and ¹⁵N₂-fixing activity (N₂FA) were 13.06 C₂H₄ nmol ml⁻¹ h⁻¹ and 2.052 ¹⁵Na.e.%, respectively. The nif gene was located in the chromosome of this strain. Based on phenotypic, physiological, biochemical and phylogenetic studies, strain HR4 could be classified as a member of D. tsuruhatensis. However, comparisons of characteristics with other known species of the genus Delftia suggested that strain HR4 was a novel dizotrophic PGPB strain.     

The Pik m gene, conferring stable resistance to isolates of Magnaporthe oryzae , was finely mapped in a crossover-cold region on rice chromosome 11

The Pik ^m gene in rice confers a high and stable resistance to many isolates of Magnaporthe oryzae collected from southern China. This gene locus was roughly mapped to the long arm of rice chromosome 11 with restriction fragment length polymorphic (RFLP) markers in the previous study. To effectively utilize the resistance, a linkage analysis was performed in a mapping population consisting of 659 highly susceptible plants collected from four F₂ populations using the publicly available simple sequence repeat (SSR) markers. The result showed that the locus was linked to the six SSR markers and defined by RM254 and RM144 with ≈13.4 and ≈1.2 cM, respectively. To fine map this locus, additional 10 PCR-based markers were developed in a region flanked by RM254 and RM144 through bioinformatics analysis (BIA) using the reference sequence of cv. Nipponbare. The linkage analysis with these 10 markers showed that the locus was further delimited to a 0.3-cM region flanked by K34 and K10, in which three markers, K27, K28, and K33, completely co-segregated with the locus. To physically map the locus, the Pik ^m -linked markers were anchored to bacterial artificial chromosome clones of the reference cv. Nipponbare by BIA. A physical map spanning ≈278 kb in length was constructed by alignment of sequences of the clones anchored by BIA, in which only six candidate genes having the R gene conserved structure, protein kinase, were further identified in an 84-kb segment.     

DNA fingerprinting of Indian isolates of Xanthomonas oryzae pv. oryzae

 A high level of genetic polymorphism was detected among Indian isolates of Xanthomonas oryzae pv. oryzae using hypervariable probes such as a microsatellite oligonucleotide, probe (TG)₁₀, a human minisatellite probe, pV47, an avirulence gene probe, avrXa10 and a repeat clone, pBS101. These DNA probes detected multiple loci in the bacterial genome generating complex DNA fingerprints and differentiated all of the bacterial isolates. Analysis of fingerprints indicated that pV47, (TG)₁₀ and pBS101 have a lower probability of identical match than avrXa10 and therefore are potential probes for DNA fingerprinting and variability analysis of Xanthomonas oryzae pv. oryzae pathogen populations. Cluster analysis based on hybridization patterns using all of the above probes showed five groups at 56% similarity. Studies on the methylation patterns of isolates representing the three important races of X. oryzae pv. oryzae indicated more methylation in the most virulent isolate, suggesting a possible role of methylation in pathogenicity. Received: 8 December 1996 / Accepted: 20 December 1996     

Relationship between Phylogeny and Pathotype for the Bacterial Blight Pathogen of Rice

Several transposable elements were isolated from the genome of Xanthomonas oryzae pv. oryzae. These elements and an avirulence gene isolated from X. oryzae pv. oryzae were used as hybridization probes for a collection of X. oryzae pv. oryzae strains from the Philippines. Each of the sequences was present in multiple copies in all strains examined and showed distinct patterns of hybridizing bands. Phenograms were derived from the restriction fragment length polymorphism data obtained for each of the individual probes and for pooled data from multiple probes. The phenograms derived from the different probes differed in topology and, on the basis of bootstrap analysis, were not equally robust. For all of the probes, including the avirulence gene, some groups (even some haplotypes) consisted of multiple races. The strains were grouped into four major clusters on the basis of the two probes giving the highest bootstrap values. These groups were inferred to represent phylogenetic lineages. Three of the six races of X. oryzae pv. oryzae appeared in more than one of the lineages, and another was present in two sublineages. For three of the races, strains representing different phenetic groups were inoculated on rice cultivars carrying 10 resistance genes. Two new races were differentiated, corresponding to pathogen lineages identified by DNA typing. On the basis of DNA and pathotypic analyses, together with information on the spatial and temporal distribution of the pathogen types from this and other studies, a general picture of X. oryzae pv. oryzae evolution in the Philippines is presented.     

Transposon-based high sequence diversity in Avr-Pita alleles increases the potential for pathogenicity of Magnaporthe oryzae populations

Magnaporthe oryzae causes rice blast that is one of the most devastating diseases of rice worldwide. Highly variable nature of this fungus has evolved itself against major resistance genes in newly released rice varieties. Understanding the population structure of this fungus is essential for proper utilization of the rice blast resistance genes in rice crop plants. In the present study, we analyzed 133 isolates of M. oryzae from ten countries to find the allelic variation of Avr-Pita gene that is triggering Pita-mediated resistance in rice plant. The diversity analysis of these alleles showed higher level of nucleotide variation in the coding regions than the noncoding regions. Evolutionary analysis of these alleles indicates that Avr-Pita gene is under purifying selection to favor its major alleles in 133 isolates analyzed in this study. We hypothesize that the selection of favorable Avr-Pita allele in these isolates may occur through a genetic mechanism known as recurrent selective sweeps. A total of 22 functional Avr-Pita protein variants were identified in this study. Insertion of Pot3 transposable element into the promoter of Avr-Pita gene was identified in virulent isolates and was suggested that mobility of repeat elements in avirulence genes of M. oryzae seems to help in emergence of new virulent types of the pathogen. Allele-specific markers developed in this study will be helpful to identify a particular type of Avr-Pita allele from M. oryzae population which can form the basis for the deployment of Pita gene in different epidemiological regions.     

Identification of flanking SSR markers for a major rice gall midge resistance gene <Emphasis Type="Italic">Gm1</Emphasis> and their validation

Host-plant resistance is the preferred strategy for management of Asian rice gall midge (Orseolia oryzae), a serious pest in many rice-growing countries. The deployment of molecular markers linked to gall midge resistance genes in breeding programmes can accelerate the development of resistant cultivars. In the present study, we have tagged and mapped a dominant gall midge resistance gene, Gm1, from the Oryza sativa cv. W1263 on chromosome 9, using SSR markers. A progeny-tested F₂ mapping population derived from the cross W1263/TN1 was used for analysis. To map the gene locus, initially a subset of the F₂ mapping population consisting of 20 homozygous resistant and susceptible lines each was screened with 63 parental polymorphic SSR markers. The SSR markers RM316, RM444 and RM219, located on chromosome 9, are linked to Gm1 at genetic distances of 8.0, 4.9 and 5.9 cM, respectively, and flank the gene locus. Further, gene/marker order was also determined. The utility of the co-segregating SSR markers was tested in a backcross population derived from the cross Swarna/W1263//Swarna, and allelic profiles of these markers were analysed in a set of donor rice genotypes possessing Gm1 and in a few gall midge-susceptible, elite rice varieties.     

High-resolution mapping and gene prediction of <Emphasis Type="Italic">Xanthomonas Oryzae</Emphasis> pv. <Emphasis Type="Italic">Oryzae</Emphasis> resistance gene <Emphasis Type="Italic">Xa7</Emphasis>

Bacterial blight (BB) caused by Xanthomonas oryzae pv. oryzae (Xoo) is a devastating disease in rice worldwide. The resistance gene Xa7, which provides dominant resistance against the pathogen with avirulence (Avr) gene AvrXa7, has proved to be durably resistant to BB. A set of SSR markers were selected from the “gramene” database based on the Xa7 gene initial mapping region on chromosome 6. These markers were used to construct a high-resolution genetic map of the chromosomal region surrounding the Xa7 gene. An F₂ mapping population with 721 highly susceptible individuals derived from a cross between the near isogenic lines (NILs) IRBB7 and IR24 were constructed to localize the Xa7 gene. In a primary analysis with eleven polymorphic SSR markers, Xa7 was located in approximately the 0.28-cM region. To walk closer to the target gene, recombinant F₂ individuals were tested using newly developed STMS (sequence tagged microsatellite) markers. Finally, the Xa7 gene was mapped to a 0.21-cM interval between the markers GDSSR02 and RM20593. The Xa7-linked markers were landed on the reference sequence of cv. Nipponbare through bioinformatics analysis. A contig map corresponding to the Xa7 gene was constructed. The target gene was assumed to span an interval of approximately 118.5-kb which contained a total of fourteen genes released by the TIGR Genome Annotation Version 5.0. Candidate-gene analysis of Xa7 revealed that the fourteen genes encode novel domains that have no amino acid sequence similar to other cloned Xa(xa) genes. Shen Chen and Zhanghui Huang are contributed equally to this work.     

Genetic and physical mapping of xa13, a recessive bacterial blight resistance gene in rice

 The recessive gene, xa13, confers resistance to Philippine race 6 (PXO99) of the bacterial blight pathogen Xanthomonas oryzae pv oryzae. Fine genetic mapping and physical mapping were conducted as initial steps in an effort to isolate the gene. Using nine selected DNA markers and two F₂ populations of 132 and 230 plants, xa13 was fine-mapped to a genomic region <4 cM on the long arm of rice chromosome 8, flanked by two RFLP markers, RG136 and R2027. Four DNA markers, RG136, R2027, S14003, and G1149, in the target region were used to identify bacterial artificial chromosome (BAC) clones potentially harboring the xa13 locus from a rice BAC library. A total of 11 BACs were identified, forming four separate contigs including a single-clone contig, 29I3, associated with the RG136 STS marker, the S14003 contig consisting of four clones (44F8, 41O2, 12A16, and 12F20), the G1149 contig with two clones, 23D11 and 21H18, and the R2027 contig consisting of four overlapping clones, 42C23, 30B5, 6B7 and 21H14. Genetic mapping indicated that the xa13 locus was contained in the R2027 contig. Chromosomal walking on the R2027 contig resulted in two more clones, 33C7 and 14L3. DNA fingerprinting showed that the six clones of the R2027 contig were overlapping. Clone 44F8 hybridized with a single fragment from the clone 14L3, integrating the R2027 and S14003 contigs into a single contig consisting of ten BAC clones with a total size of approximately 330 kb. The physical presence of the xa13 locus in the contig was determined by mapping the ends of the BAC inserts generated by TAIL-PCR. In an F₂ population of 230 plants, the BAC-end markers 42C23R and 6B7F flanked the xa13 locus. The probes 21H14F and 21H14R derived from BAC clone 21H14 were found to flank xa13 at a distance of 0.5 cM on either side, using a second F₂ population of 132 plants. Thus, genetic mapping indicated that the contig and the 96-kb clone, 21H14, contained the xa13 locus. Received: 15 August 1998 / Accepted: 29 September 1998     

Molecular mapping of two cultivar-specific avirulence genes in the rice blast fungus <Emphasis Type="Italic">Magnaporthe grisea</Emphasis>

Rice blast, caused by the fungus Magnaporthe grisea, is a globally important disease of rice that causes annual yield losses. The segregation of genes controlling the virulence of M. grisea on rice was studied to establish the genetic basis of cultivar specificity in the interaction of rice and M. grisea. The segregation of avirulence and virulence was studied in 87 M. grisea F₁ progeny isolates from a cross of two isolates, Guy11 and JS153, using resistance-gene-differential rice cultivars. The segregation ratio indicated that avirulence and virulence in the rice cultivars Aichi–asahi and K59, respectively, are controlled by single major genes. Genetic analyses of backcrosses and full-sib crosses in these populations were also performed. The χ² test of goodness-of-fitness for a 1:1 ratio indicated that one dominant gene controls avirulence in Aichi-asahi and K59 in this population. Based on the resistance reactions of rice differential lines harboring known resistance genes to the parental isolates, two genetically independent avirulence genes, AVR–Pit and AVR–Pia, were identified. Genetic linkage analysis showed that the SSR marker m355–356 is closely linked to AVR–Pit, on the telomere of chromosome 1 at a distance of approximately 2.3 cM. The RAPD marker S487, which was converted to a sequence-characterized amplified region (SCAR) marker, was found to be closely linked to AVR–Pia, on the chromosome 7 telomere at a distance of 3.5 cM. These molecular markers will facilitate the positional cloning of the two AVR genes, and can be applied to molecular-marker-assisted studies of M. grisea populations.     

Cytomolecular discrimination of the A<Superscript>m</Superscript> chromosomes of <Emphasis Type="Italic">Triticum monococcum</Emphasis> and the A chromosomes of <Emphasis Type="Italic">Triticum aestivum</Emphasis> using microsatellite DNA repeats

The cytomolecular discrimination of the A^m- and A-genome chromosomes facilitates the selection of wheat-Triticum monococcum introgression lines. Fluorescence in situ hybridisation (FISH) with the commonly used DNA probes Afa family, 18S rDNA and pSc119.2 showed that the more complex hybridisation pattern obtained in T. monococcum relative to bread wheat made it possible to differentiate the A^m and A chromosomes within homoeologous groups 1, 4 and 5. In order to provide additional chromosomal landmarks to discriminate the A^m and A chromosomes, the microsatellite repeats (GAA)_n, (CAG)_n, (CAC)_n, (AAC)_n, (AGG)_n and (ACT)_n were tested as FISH probes. These showed that T. monococcum chromosomes have fewer, generally weaker, simple sequence repeat (SSR) signals than the A-genome chromosomes of hexaploid wheat. A differential hybridisation pattern was observed on 6A^m and 6A chromosomes with all the SSR probes tested except for the (ACT)_n probe. The 2A^m and 2A chromosomes were differentiated by the signals given by the (GAA)_n, (CAG)_n and (AAC)_n repeats, while only (GAA)_n discriminated the chromosomes 3A^m and 3A. Chromosomes 7A^m and 7A could be differentiated by the lack of (GAA)_n and (AGG)_n signals on 7A. As potential landmarks for identifying the A^m chromosomes, SSR repeats will facilitate the introgression of T. monococcum chromatin into wheat.     

High-resolution genetic mapping of bacterial blight resistance gene <Emphasis Type="Italic">Xa10</Emphasis>

Bacterial blight of rice, caused by Xanthomonas oryzae pv. oryzae (Xoo), is the most devastating disease of rice (Oryza sativa L). Rice lines that carry resistance (R) gene Xa10 confer race-specific resistance to Xoo strains harboring avirulence (Avr) gene avrXa10. Here we report on genetic study, disease evaluation and fine genetic mapping of the Xa10 gene. The inheritance of Xa10-mediated resistance to PXO99^A(pHM1avrXa10) did not follow typical Mendelian inheritance for single dominant gene in F₂ population derived from IR24 × IRBB10. A locus might be present in IRBB10 that caused distorted segregation in F₂ population. To eliminate this locus, an F₃ population (F₃-65) was identified, which showed normal Mendelian segregation ratio of 3:1 for resistance and susceptibility. A new near-isogenic line (F₃-65-1743) of Xa10 in IR24 genetic background was developed and designated as IRBB10A. IRBB10A retained similar resistance specificity as that of IRBB10 and provided complete resistance to PXO99^A(pHM1avrXa10) from seedling to adult stages. Linkage analysis using existing RFLP markers and F₂ mapping population mapped the Xa10 locus to the proximal side of E1981S with genetic distance at 0.93 cM. With five new RFLP markers developed from the genomic sequence of Nipponbare, Xa10 was finely mapped at genetic distance of 0.28 cM between proximal marker M491 and distal marker M419 and co-segregated with markers S723 and M604. The physical distance between M491 and M419 on Nipponbare genome is 74 kb. Seven genes have been annotated from this 74-kb region and six of them are possible Xa10 candidates. The results of this study will be useful in Xa10 cloning and marker-assisted breeding.     

Population structure analysis and association mapping of bacterial blight resistance in <Emphasis Type="Italic">indica</Emphasis> rice (<Emphasis Type="Italic">Oryza sativa</Emphasis> L.) accessions

Bacterial blight, caused by Xanthomonas oryzae pv. oryzae (Xoo), is a serious disease in rice production worldwide. To understand the genetic diversity of bacterial blight resistance a population consisting of 175 indica accessions from nine countries was collected and detected their association between SSR (Simple Sequence Repeat) markers and resistance to six bacterial races. The resistance phenotypes of various rice accessions were evaluated through artificial inoculation under controlled conditions in 2013 and 2014. Association analysis showed that 17 SSR markers were significantly associated with resistance to four bacterial races and the phenotypic variations explained (PVE) ranged from 7.43 to 15.05%. Among the 17 associated SSR markers, two SSR markers located in previously reported genes regions, and 15 SSR markers were newly identified in this study. These results validated a new approach to map resistance genes of rice to bacterial blight. These markers could be used for marker-assisted selection (MAS) in rice bacterial blight resistance breeding programs.     

A Rapid and Simple Method for DNA Preparation of Magnaporthe oryzae from Single Rice Blast Lesions for PCR-Based Molecular Analysis

Rice blast is one of the most destructive diseases of rice worldwide, and the causative agent is the filamentous ascomycete Magnaporthe oryzae. With the successful cloning of more and more avirulence genes from M. oryzae, the direct extraction of M. oryzae genomic DNA from infected rice tissue would be useful alternative for rapid monitoring of changes of avirulence genes without isolation and cultivation of the pathogen. In this study, a fast, low-cost and reliable method for DNA preparation of M. oryzae from a small piece of infected single rice leaf or neck lesion was established. This single step method only required 10 min for DNA preparation and conventional chemical reagents commonly found in the laboratory. The AvrPik and AvrPi9 genes were successfully amplified with the prepared DNA. The expected DNA fragments from 570 bp to 1,139 bp could be amplified even three months after DNA preparation. This method was also suitable for DNA preparation from M. oryzae strains stored on the filter paper. All together these results indicate that the DNA preparation method established in this study is reliable, and could meet the basic needs for polymerase chain reaction-based analysis of M. oryzae.     

Association Genetics Reveals Three Novel Avirulence Genes from the Rice Blast Fungal Pathogen Magnaporthe oryzae

To subvert rice (Oryza sativa) host defenses, the devastating ascomycete fungus pathogen Magnaporthe oryzae produces a battery of effector molecules, including some with avirulence (AVR) activity, which are recognized by host resistance (R) proteins resulting in rapid and effective activation of innate immunity. To isolate novel avirulence genes from M. oryzae, we examined DNA polymorphisms of secreted protein genes predicted from the genome sequence of isolate 70-15 and looked for an association with AVR activity. This large-scale study found significantly more presence/absence polymorphisms than nucleotide polymorphisms among 1032 putative secreted protein genes. Nucleotide diversity of M. oryzae among 46 isolates of a worldwide collection was extremely low (θ = 8.2 × 10⁻⁵), suggestive of recent pathogen dispersal. However, no association between DNA polymorphism and AVR was identified. Therefore, we used genome resequencing of Ina168, an M. oryzae isolate that contains nine AVR genes. Remarkably, a total of 1.68 Mb regions, comprising 316 candidate effector genes, were present in Ina168 but absent in the assembled sequence of isolate 70-15. Association analyses of these 316 genes revealed three novel AVR genes, AVR-Pia, AVR-Pii, and AVR-Pik/km/kp, corresponding to five previously known AVR genes, whose products are recognized inside rice cells possessing the cognate R genes. AVR-Pia and AVR-Pii have evolved by gene gain/loss processes, whereas AVR-Pik/km/kp has evolved by nucleotide substitutions and gene gain/loss.     

Construction and characterization of a bacterial artificial chromosome library of thermo-sensitive genie male-sterile rice 5460S

In order to develop a detailed physical map of the thermo-sensitive genie male-sterile (TGMS) gene-encompassing region and finally clone the TGMS gene, a high-quality rice bacterial artificial chromosome (BAC) library from TGMS rice 5460S was constructed. The method of constructing BAC library was examined and optimized. The 5460S library consists of 19 584 BAC clones with an average insert size of 110 kb, which represents about 5 times rice haploid genome equivalents. Rice inserts of up to 140 kb and 250 kb were isolated and appeared stable after 100 generations of serial growth. Hybridization of BAC clones with mitochondrial and chloroplastic genes as probes demonstrated that this library has no organellar contamination. The 5460S library was screened with 3 molecular markers linked to tmsl gene as probes and at least 1 BAC clone was identified with each probe. The insert ends of positive clones were successfully isolated using thermal asymmetric interlaced PCR (TAIL-PCR) technique.     

Genetic analysis and molecular mapping of a novel recessive gene xa34(t) for resistance against Xanthomonas oryzae pv. oryzae

A new bacterial blight recessive resistance gene xa34(t) was identified from the descendant of somatic hybridization between an aus rice cultivar (cv.) BG1222 and susceptible cv. IR24 against Chinese race V (isolate 5226). The isolate was used to test the resistance or susceptibility of F₁ progenies and reciprocal crosses of the parents. The results showed that F₁ progenies appeared susceptibility there were 128R (resistant):378S (susceptible) and 119R:375S plants in F₂ populations derived from two crosses of BG1222/IR24 and IR24/BG1222, respectively, which both calculates into a 1R:3S ratio. 320 pairs of stochastically selected SSR primers were used for genes?? initial mapping. The screened results showed that two SSR markers, RM493 and RM446, found on rice chromosome 1 linked to xa34(t). Linkage analysis showed that these two markers were on both sides of xa34(t) with the genetic distances 4.29 and 3.05?cM, respectively. The other 50 SSR markers in this region were used for genes?? fine mapping. The further results indicated that xa34(t) was mapped to a 1.42?cM genetic region between RM10927 and RM10591. In order to further narrow down the genomic region of xa34(t), 43 of insertion/deletion (Indel) markers (BGID1-43) were designed according to the sequences comparison between japonica and indica rice. Parents?? polymorphic detection and linkage assay showed that the Indel marker BGID25 came closer to the target gene with a 0.4?cM genetic distance. A contig map corresponding to the locus was constructed based on the reference sequences aligned by the xa34(t) linked markers. Consequently, the locus of xa34(t) was defined to a 204?kb interval flanked by markers RM10929 and BGID25.     

Fine Mapping of Xa2, a Bacterial Blight Resistance Gene in Rice

The rice bacterial blight resistance gene, Xa2, confers resistance to T7147 of the bacterial blight pathogen Xanthomonas oryzae pv. oryzae. It is located on the long arm of chromosome 4. Here, we report the fine mapping of Xa2 by genetic recombination analysis with simple sequence repeat (SSR) markers according to the genome sequence. Two F₂ populations are constructed to localize Xa2. In a primary analysis with 136 random F₂ plants of Zhenzhuai/IRBB2, it was found that Xa2 was located in approximately 20 cM region. To accurately determine the locus of Xa2, 120 new SSR markers were developed in this region by screening the sequence. Twelve new SSR markers were successfully used in genetic recombination analysis in IR24/IRBB2 population, while 20 in ZZA/IRBB2 population. We found that the nearest SSR markers to Xa2 are HZR950-5 and HZR970-4, which cover approximately 190-kb region. The sequence analysis of this 190-kb region revealed the presence of a homologous sequence of leucine rich repeat (LRR)-kinase. These results are very useful for transferring or pyramiding Xa2 by molecular marker-assistant selection in rice breeding programs and for cloning Xa2 by map-based cloning in combination with a long-range PCR strategy. Electronic supplementary material Electronic supplementary material is available for this article at and accessible for authorised users.