Cloning and in silico Mapping of Resistance Gene Analogues Isolated from Rice Lines Containing Known Genes for Blast Resistance

We amplified resistance gene analogues (RGAs) from the genomic DNA of 10 rice lines having varying degree of resistance to Magnaporthe grisea by using degenerate primers and various RGAs were mapped in silico on different rice chromosomes. The amplified products were grouped into 3–8 restriction fragment length polymorphic classes by using Mbo1 and Alu1 restriction enzymes. Of 98 RGAs obtained in this study, 65 RGA clones showed more than 95% homology with various RGAs sequences present in the GenBank. Phylogenetic analysis of these RGAs formed 11 groups. Using sequence homology approach, RGAs isolated in this study were physically mapped on 23 loci on chromosomes 1, 2, 3, 4, 5, 6, 7, 8, 10, 11 and 12. Twenty RGAs were mapped near to the chromosomal regions containing known genes/QTLs for rice blast, bacterial leaf blight and sheath blight resistance. Thirty‐nine RGA sequences also contained open reading frame representing signature of potential disease resistance genes.     

Isolation,Cloning and Characterization of Resistance Gene Analogues in Pearl Millet Based on Conserved Nucleotide‐binding Sites

Sequence analysis of plant disease resistance genes shows similarity among themselves, with the presence of conserved motifs common to the nucleotide‐binding site (NBS). Oligonucleotide degenerate primers designed from the conserved NBS motifs encoded by several plant disease resistance genes were used to amplify resistance gene analogues (RGAs) corresponding to the NBS sequences from the genomic DNA of various plant species. Using specific primers designed from the conserved NBS regions, 22 RGAs were cloned and sequenced from pearl millet (Pennisetum glaucum L. Br.). Phylogenetic analysis of the predicted amino acid sequences grouped the RGAs into nine distinct classes. GenBank database searches with the consensus protein sequences of each of the nine classes revealed their conserved NBS domains and similarity to other known R genes of various crop species. One RGA 213 was mapped onto LG1 and LG7 in the pearl millet linkage map. This is the first report of the isolation and characterization of RGAs from pearl millet, which will facilitate the improvement of marker‐assisted breeding strategies.     

小麦NBS-LRR类抗病基因同源序列的分离与鉴定

根据已知植物抗病基因的保守区域设计引物,从抗锈病小麦品种西农88基因组DNA扩增出3条与植物抗病基因同源的序列,分别为WRGA1、WRGA2和WRGA14。这三条同源片段均含有典型的NBS-LRR类抗病基因所拥有的保守性结构域Kinase-2a、Kinase-3a和疏水结构域(HD)．它们与部分已知NBS-LRR类抗病基因的氨基酸序列同源性为46．0%-9．9%,三个片段间在氨基酸水平上的同源性为80．7%-56．8%。Northern杂交表明WRGA1在小麦中受水杨酸正调控,属诱导型表达。     

Cloning and characterisation of a family of disease resistance gene analogs from wheat and barley

 The most common class of plant disease resistance (R) genes cloned so far belong to the NBS-LRR group which contain nucleotide-binding sites (NBS) and a leucine-rich repeat (LRR). Specific primer sequences derived from a previously isolated NBS-LRR sequence at the Cre3 locus, which confers resistance to cereal cyst nematode (CCN) in wheat (Triticum aestivum L.) were used in isolating a family of resistance gene analogs (RGA) through a polymerase chain reaction (PCR) cloning approach. The cloning, analysis and genetic mapping of a family of RGAs from wheat (cv ‘Chinese Spring’) and barley (Hordeum vulgare L. cvs ‘Chebec’ and ‘Harrington’) are presented. The wheat and barley RGAs contain other conserved motifs present in known R genes from other plants and share between 55–99% amino acid sequence identity to the NBS-LRR sequence at the Cre3 locus. Phylogenetic analysis of the RGAs with other cloned R genes and RGAs from various plant species indicate that they belong to a superfamily of NBS-containing genes. Two of the barley derived RGAs were mapped onto loci on chromosomes 2H (2), 5H (7) and 7H (1) using barley doubled haploid (DH) mapping populations. Some of these loci identified are associated with regions carrying resistance to CCN and corn leaf aphid. Received: 6 January 1998 / Accepted: 1 April 1998     

Characterisation of disease resistance gene-like sequences in Brassica oleracea L.

Several cloned disease resistance genes from a wide range of plant species are known to share conserved regions with similar structural motifs. Degenerate primers based on conserved sequences of the nucleotide binding site of the genes RPS2, N and L6 were used for polymerase chain reaction (PCR) amplification from genomic DNA of two doubled haploid lines of Brassica oleracea. Sequences of amplified products were highly variable, but most of them showed similarity to known disease resistance genes, including RPS5, RPS2 and N, and to disease resistance gene-like sequences (RGLs) from different species. Primers based on B. oleracea sequences amplified five groups of RGLs. Products were mapped through cleaved amplified polymorphic sequence assays onto four different linkage groups of B. oleracea. PCR amplification from cDNA and allele analysis indicated that four locus-specific RGL fragments are expressed in cauliflower. Screening of a B. oleracea bacterial artificial chromosome library (BAC) with four B. oleracea RGL probes identified a small number of clones, suggesting that the four RGLs may not be highly copied. Screening of a BAC library of A. thaliana with the same probes identified clones that mapped onto four different chromosomes. These map positions correspond to known disease resistance loci of A. thaliana. Received: 12 November 1999 / Accepted: 19 June 2000     

Identification of resistance gene analogs linked to a powdery mildew resistance locus in grapevine

Oligonucleotide primers, designed to conserved regions of nucleotide binding site (NBS) motifs within previously cloned pathogen resistance genes, were used to amplify resistance gene analogs (RGAs) from grapevine. Twenty eight unique grapevine RGA sequences were identified and subdivided into 22 groups on the basis of nucleic acid sequence-identity of approximately 70% or greater. Representatives from each group were used in a bulked segregant analysis strategy to screen for restriction fragment length polymorphisms linked to the powdery mildew resistance locus, Run1, introgressed into Vitis vinifera L. from the wild grape species Muscadinia rotundifolia. Three RGA markers were found to be tightly linked to the Run1 locus. Of these markers, two (GLP1–12 and MHD145) cosegregated with the resistance phenotype in 167 progeny tested, whereas the third marker (MHD98) was mapped to a position 2.4 cM from the Run1 locus. The results demonstrate the usefulness of RGA sequences, when used in combination with bulked segregant analysis, to rapidly generate markers tightly linked to resistance loci in crop species. Received: 2 May 2001 / Accepted: 3 August 2001     

NBS-LRR resistance gene homologues in rice

Twenty three DNA fragments with a size of about 520 bp have been cloned from rice genome by PCR amplification using primers designed according to the conserved region of most plant resistance (R) genes which have Nucleotide Binding Site (NBS) and Leucine-Rich Repeat (LRR) domains. Homologous comparison showed that these fragments contained typical motifs of the NBS-LRR resistance gene class, kinase 1a, kinase 2a, kinase 3a and domain 2. Thus they were named R gene homologous sequences (RS). These RS were divided into 4 groups by clustering analysis and mapped onto chromosomes 1, 3, 4, 7, 8, 9, 10 and 11, respectively, by genetic mapping. Ten RS were located in the chromosomal intervals where known R genes had been mapped. Further RFLP analysis of an RS, RS13, near the bacterial blight resistance geneXa4 locus on chromosome 11 among near isogenic lines and pyramiding lines ofXa4 showed that RS13 was possibly amplified from the gene family ofXa4.     

Isolation,genetic variation and expression of TIR-NBS-LRR resistance gene analogs from western white pine (<Emphasis Type="Italic">Pinus monticola </Emphasis>Dougl. ex. D. Don.)

Western white pine (Pinus monticola Dougl. ex. D. Don., WWP) shows genetic variation in disease resistance to white pine blister rust (Cronartium ribicola). Most plant disease resistance (R) genes encode proteins that belong to a superfamily with nucleotide-binding site domains (NBS) and C-terminal leucine-rich repeats (LRR). In this work a PCR strategy was used to clone R gene analogs (RGAs) from WWP using oligonucleotide primers based on the conserved sequence motifs in the NBS domain of angiosperm NBS-LRR genes. Sixty-seven NBS sequences were cloned from disease-resistant trees. BLAST searches in GenBank revealed that they shared significant identity to well-characterized R genes from angiosperms, including L and M genes from flax, the tobacco N gene and the soybean gene LM6. Sequence alignments revealed that the RGAs from WWP contained the conserved motifs identified in angiosperm NBS domains, especially those motifs specific for TIR-NBS-LRR proteins. Phylogenic analysis of plant R genes and RGAs indicated that all cloned WWP RGAs can be grouped into one major branch together with well-known R proteins carrying a TIR domain, suggesting they belong to the subfamily of TIR-NBS-LRR genes. In one phylogenic tree, WWP RGAs were further subdivided into fourteen clusters with an amino acid sequence identity threshold of 75%. cDNA cloning and RT-PCR analysis with gene-specific primers demonstrated that members of 10 of the 14 RGA classes were expressed in foliage tissues, suggesting that a large and diverse NBS-LRR gene family may be functional in conifers. These results provide evidence for the hypothesis that conifer RGAs share a common origin with R genes from angiosperms, and some of them may play important roles in defense mechanisms that confer disease resistance in western white pine. Ratios of non-synonymous to synonymous nucleotide substitutions (Ka/Ks) in the WWP NBS domains were greater than 1 or close to 1, indicating that diversifying selection and/or neutral selection operate on the NBS domains of the WWP RGA family.Communicated by R. Hagemann     

Molecular characterization of cDNA encoding resistance gene-like sequences in Buchloe dactyloides

Current knowledge of resistance (R) genes and their use for genetic improvement in buffalograss (Buchloe dactyloides [Nutt.] Engelm.) lag behind most crop plants. This study was conducted to clone and characterize cDNA encoding R gene-like (RGL) sequences in buffalograss. This report is the first to clone and characterize of buffalograss RGLs. Degenerate primers designed from the conserved motifs of known R genes were used to amplify RGLs and fragments of expected size were isolated and cloned. Sequence analysis of cDNA clones and analysis of putative translation products revealed that most encoded amino acid sequences shared the similar conserved motifs found in the cloned plant disease resistance genes PRS2, MLA6, L6, RPMI, and Xa1. These results indicated diversity of the R gene candidate sequences in buffalograss. Analysis of 5′ rapid amplification of cDNA ends (RACE), applied to investigate upstream of RGLs, indicated that regulatory sequences such as TATA box were conserved among the RGLs identified. The cloned RGL in this study will further enhance our knowledge on organization, function, and evolution of R gene family in buffalo grass. With the sequences of the primers and sizes of the markers provided, these RGL markers are readily available for use in a genomics-assisted selection in buffalograss.     

Isolation and mapping of resistance gene analogs from the Avena strigosa genome

Degenerate primers based on conserved regions of the nucleotide binding site (NBS) domain (encoded by the largest group of cloned plant disease resistance genes) were used to isolate a set of 15 resistance gene analogs (RGA) from the diploid species Avena strigosa Schreb. These were grouped into seven classes on the basis of 60% or greater nucleic acid sequence identity. Representative clones were used for genetic mapping in diploid and hexaploid oats. Two RGAs were mapped at two loci of the linkage group AswBF belonging to the A. strigosa × A. wiestii Steud map, and ten RGAs were mapped at 15 loci in eight linkage groups belonging to the A. byzantina C. Koch cv. Kanota × A. sativa L. cv. Ogle map. A similar approach was used for targeting genes encoding receptor-like kinases. Three different sequences were obtained and mapped to two linkage groups of the hexaploid oat map. Associations were explored between already known disease resistance loci mapped in different populations and the RGAs. Molecular markers previously linked to crown rust and barley yellow dwarf resistance genes or quantitative trait loci were found in the Kanota × Ogle map linked to RGAs at a distance ranging from 0 cM to 20 cM. Homoeologous RGAs were found to be linked to loci either conferring resistance to different isolates of the same pathogen or to different pathogens. This suggests that these RGAs identify genome regions containing resistance gene clusters.     

The Absence of TIR-Type Resistance Gene Analogues in the Sugar Beet (Beta vulgaris L.) Genome

The majority of known plant resistance genes encode proteins with conserved nucleotide-binding sites and leucine-rich repeats (NBS-LRR). Degenerate primers based on conserved NBS-LRR motifs were used to amplify analogues of resistance genes from the dicot sugar beet. Along with a cDNA library screen, the PCR screen identified 27 genomic and 12 expressed NBS-LRR RGAs (nlRGAs) sugar beet clones. The clones were classified into three subfamilies based on nucleotide sequence identity. Sequence analyses suggested that point mutations, such as nucleotide substitutions and insertion/deletions, are probably the primary source of diversity of sugar beet nlRGAs. A phylogenetic analysis revealed an ancestral relationship among sugar beet nlRGAs and resistance genes from various angiosperm species. One group appeared to share the same common ancestor as Prf, Rx, RPP8, and Mi, whereas the second group originated from the ancestral gene from which 12C1, Xa1, and Cre3 arose. The predicted protein products of the nlRGAs isolated in this study are all members of the non-TIR-type resistance gene subfamily and share strong sequence and structural similarities with non-TIR-type resistance proteins. No representatives of the TIR-type RGAs were detected either by PCR amplification using TIR type-specific primers or by in silico screening of more than 16,000 sugar beet ESTs. These findings suggest that TIR type of RGAs is absent from the sugar beet genome. The possible evolutionary loss of TIR type RGAs in the sugar beet is discussed. These authors (Yanyan Tian, Longjiang Fan) contributed equally to this work.     

野生稻NBS类抗病基因同源序列的分离与序列分析

为了挖掘野生稻中的抗病资源,根据已克隆的植物抗病基因核苷酸结合位点序列中的保守结构域设计3对简并引物,从疣粒、药用、高秆、宽叶和斑点野生稻基因组DNA中分离出13条NBS类抗病基因类似物,其中11条具有连续的ORF,具有NBS类R基因的保守基元P-loop、kinas-2、kinas-3a和GLPL。在NCBI上进行同源性搜索发现,其中12条RGAs的核苷酸序列与水稻已知的NBS类R基因具有66%～94%的同源性,与其他植物已知R基因具有67%～84%的同源性;其对应的氨基酸序列与水稻已知的NBS类R基因具有43%～93%的同源性,与其他植物已知R基因具有37%～79%的同源性。另外1条的核苷酸序列与水稻假定的NBS类R基因具有76%的同源性,其氨基酸序列与水稻假定的NBS类R基因具有74%的同源性。根据序列分析结果设计6对不同基因特异性引物,并利用RT-PCR技术进行表达分析,结果表明,RN1BD5、RN1BD10、RN1GG2和RN1YY6均能表达,说明这些片段可能是功能性抗病基因的部分序列;而RN1KY9和RN1GG5没有表达,可能是假基因。     

Isolation and linkage mapping of NBS-LRR resistance gene analogs in red raspberry (<Emphasis Type="Italic">Rubus idaeus</Emphasis> L.) and classification among 270 Rosaceae NBS-LRR genes

Plant R genes confer resistance to pathogens in a gene-for-gene mode. Seventy-five putative resistance gene analogs (RGAs) containing conserved domains were cloned from Rubus idaeus L. cv. ‘Latham’ using degenerate primers based on RGAs identified in Rosaceae species. The sequences were compared to 195 RGA sequences identified from five Rosaceae family genera. Multiple sequence alignments showed high similarity at multiple nucleotide-binding site (NBS) motifs with homology to Drosophila Toll and mammalian interleukin-1 receptor (TIR) and non-TIR RNBSA-A motifs. The TIR sequences clustered separately from the non-TIR sequences with a bootstrap value of 76%. There were 11 clusters each of TIR and non-TIR type sequences of multiple genera with bootstrap values of more than 50%, including nine with values of more than 75% and seven of more than 90%. Polymorphic sequence characterized amplified region and cleaved amplified polymorphic sequence markers were developed for nine Rubus RGA sequences with eight placed on a red raspberry genetic linkage map. Phylogenetic analysis indicated four of the mapped sequences share sequence similarity to groupTIR I, while three others were spread in non-TIR groups. Of the 75 Rubus RGA sequences analyzed, members were placed in five TIR groups and six non-TIR groups. These group classifications closely matched those in 12 of 13 studies from which these sequences were derived. The analysis of related DNA sequences within plant families elucidates the evolutionary relationship and process involved in pest resistance development in plants. This information will aid in the understanding of R genes and their proliferation within plant genomes. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Isolation of TIR and nonTIR NBS–LRR resistance gene analogues and identification of molecular markers linked to a powdery mildew resistance locus in chestnut rose (Rosa roxburghii Tratt)

Toll and interleukin-1 receptor (TIR) and nonTIR nucleotide binding site–leucine rich repeat (NBS–LRR) resistance gene analogues (RGAs) were obtained from chestnut rose (Rosa roxburghii Tratt) by two PCR-based amplification strategies (direct amplification and overlap extension amplification) with degenerate primers designed to the conserved P-loop, kinase-2, and Gly-Leu-Pro-Leu (GLPL) motifs within the NBS domain of plant resistance gene (R gene) products. Thirty-four of 65 cloned PCR fragments contained a continuous open reading frame (ORF) and their predicted protein products showed homology to the NBS–LRR class R proteins in the GenBank database. These 34 predicted protein sequences exhibited a wide range (19.5–99.4%) of sequence identity among them and were classified into two distinct groups by phylogenetic analysis. The first group consisted of 23 sequences and seemed to belong to the nonTIR NBS–LRR RGAs, since they contained group specific motifs (RNBS-A-nonTIR motif) that are often present in the coiled-coil domain of the nonTIR NBS–LRR class R genes. The second group comprised 11 sequences that contained motifs found in the TIR domain of TIR NBS–LRR class R genes. Restriction fragment length polymorphic (RFLP) markers were developed from some of the RGAs and used for mapping powdery mildew resistance genes in chestnut rose. Three markers, RGA22C, RGA4A, and RGA7B, were identified to be linked to a resistance gene locus, designated CRPM1 for chestnut rose powdery mildew resistance 1, which accounted for 72% of the variation in powdery mildew resistance phenotype in an F1 segregating population. To our knowledge, this is the first report on isolation, phylogenetic analysis and potential utilization as genetic markers of RGAs in chestnut rose.     

Genome scanning for resistance-gene analogs in rice, barley, and wheat by high-resolution electrophoresis

 Genes cloned from diverse plants for resistance to different pathogens have sequence similarities in domains presumably involved in pathogen recognition and signal transduction in triggering the defense response. Primers based on the conserved regions of resistance genes often amplify multiple fragments that may not be separable in an agarose gel. We used denaturing polyacrylamide-gel electrophoresis to detect PCR products of plant genomic DNA amplified with primers based on conserved regions of resistance genes. Depending upon the primer pairs used, 30–130 bands were detected in wheat, rice, and barley. As high as 47%, 40%, and 27% of the polymorphic bands were detected in rice, barley, and wheat, respectively, and as high as 12.5% of the polymorphic bands were detected by certain primers in progeny from a cross of the wheat cultivars ‘Stephens’ and ‘Michigan Amber’. Using F₆ recombinant inbred lines from the ‘Stephens’בMichigan Amber’ cross, we demonstrated that polymorphic bands amplified with primers based on leucine-rich repeats, nucleotide-binding sites and protein kinase genes, were inherited as single loci. Linkages between molecular markers and stripe rust resistance genes were detected. This technique provides a new way to develop molecular markers for assessing the genetic diversity of germplasm based upon potential candidate resistance genes in diverse species. Received : 5 September 1997 / Accepted : 6 November 1997     

Characterization and mapping of NBS-LRR resistance gene analogs in apricot (Prunus armeniaca L.)

Genomic DNA sequences sharing homology with the NBS-LRR (nucleotide binding site-leucine-rich repeat) resistance genes were isolated and cloned from apricot (Prunus armeniaca L.) using a PCR approach with degenerate primers designed from conserved regions of the NBS domain. Restriction digestion and sequence analyses of the amplified fragments led to the identification of 43 unique amino acid sequences grouped into six families of resistance gene analogs (RGAs). All of the RGAs identified belong to the Toll-Interleukin receptor (TIR) group of the plant disease resistance genes (R-genes). RGA-specific primers based on non-conserved regions of the NBS domain were developed from the consensus sequences of each RGA family. These primers were used to develop amplified fragment length polymorphism (AFLP)-RGA markers by means of an AFLP-modified procedure where one standard primer is substituted by an RGA-specific primer. Using this method, 27 polymorphic markers, six of which shared homology with the TIR class of the NBS-LRR R-genes, were obtained from 17 different primer combinations. Of these 27 markers, 16 mapped in an apricot genetic map previously constructed from the self-pollination of the cultivar Lito. The development of AFLP-RGA markers may prove to be useful for marker-assisted selection and map-based cloning of R-genes in apricot.     

Genetic Analysis of Resistance Gene Analogues from a Sugarcane Cultivar Resistant to Red Rot Disease

One of the important approaches for disease control in sugarcane is to develop a disease‐resistant variety; this may be accomplished through identification of resistance genes in sugarcane. In this study, PCR primers targeting the conserved motifs of the nucleotide‐binding site (NBS) class and kinase class of the resistance gene analogues (RGAs) were used to amplify the RGAs from a red rot‐resistant sugarcane cultivar (Saccharum spp. hybrid) HSF 240. Upon subcloning and sequencing, fifteen putative RGAs were identified. These RGAs shared 63–98% identity to the reported disease‐resistant genes in the NCBI GenBank database. Deduced amino acid sequences also showed the presence of expected conserved domains characteristic of RGAs. Phylogenetic analysis indicated that these RGAs clustered with R genes from other plant species. The findings will be useful for studying disease‐resistant genes in sugarcane.     

Characterization and linkage mapping of R-gene analogous DNA sequences in pea (Pisum sativum L.)

Pea (Pisum sativum L.) sequences that are analogous to the conserved nucleotide binding site (NBS) domain found in a number of plant disease resistance genes (R-genes) were cloned. Using redundant oligonucleotide primers and the polymerase chain reaction (PCR), we amplified nine pea sequences and characterised their sequences. The pea R-gene analog (RGA)- deduced amino acid sequences demonstrated significant sequence similarity with known R-gene sequences lodged in public databases. The genomic locations of eight of the pea RGAs were determined by linkage mapping. The eight RGAs identified ten loci that mapped to six linkage groups. In addition, the genomic organization of the RGAs was inferred. Both single-copy and multicopy sequence families were present among the RGAs, and the multicopy families occurred most often as tightly linked clusters of related sequences. Intraspecific copy number variability was observed in three of the RGA sequence families, suggesting that these sequence families are evolving rapidly. The genomic locations of the pea RGAs were compared with the locations of known pea R-genes and sym genes involved in the pea-rhizobia symbiosis. Two pea RGAs mapped in the genomic region containing a pea R-gene, Fw, and four pea RGAs mapped in regions of the genome containing sym genes. Received: 4 August 1999 / Accepted: 11 November 1999     

Resistance gene analogue markers are mapped to homeologous chromosomes in cultivated tetraploid cotton

Degenerate primers designed from conserved motifs of known plant resistance gene products were used to amplify genomic DNA sequences from the root-knot nematode (Meloidogyne incognita) resistance genetic source, Upland cotton (Gossypium hirsutum) cultivar Auburn 634 RNR. A total of 165 clones were isolated, and sequence analysis revealed 57 of the clones to be novel nucleotide sequences, many containing the resistance (R)-protein nucleotide-binding site motif. A cluster analysis was performed with resistance gene analogue (RGA) nucleotide sequences isolated in this study, in addition to 99 cotton RGA nucleotide sequences already deposited in GenBank, to generate a phylogenetic tree of cotton R genes. The cotton RGA nucleotide sequences were arranged into 11 groups and 56 sub-groups, based on genetic distances. Multiple sequence alignments were performed on the RGA sequences of each sub-group, and either the consensus sequences or individual RGA sequences were used to design 61 RGA-sequence-tagged site primers. A recombinant inbred line (RIL) population of cultivated tetraploid cotton was genotyped using RGA-specific primers that amplified polymorphic fragments between the two RIL parents. Nine RGA markers were mapped to homeologous chromosomes 12 and 26, based on linkage to existing markers that are located on these chromosomes.     

Tagging and mapping of a rice gall midge resistance gene, <Emphasis Type="Italic">Gm8</Emphasis>, and development of SCARs for use in marker-aided selection and gene pyramiding

Using amplified fragment length polymorphisms (AFLPs) and random amplified polymorphic DNAs (RAPDs), we have tagged and mapped Gm8, a gene conferring resistance to the rice gall midge (Orseolia oryzae), a major insect pest of rice, onto rice chromosome 8. Using AFLPs, two fragments, AR257 and AS168, were identified that were linked to the resistant and susceptible phenotypes, respectively. Another resistant phenotype-specific marker, AP19₅₈₇, was also identified using RAPDs. SCAR primers based on the sequence of the fragments AR257 and AS168 failed to reveal polymorphism between the resistant and the susceptible parents. However, PCR using primers based on the regions flanking AR257 revealed polymorphism that was phenotype-specific. In contrast, PCR carried out using primers flanking the susceptible phenotype-associated fragment AS168 produced a monomorphic fragment. Restriction digestion of these monomorphic fragments revealed polymorphism between the susceptible and resistant parents. Nucleotide BLAST searches revealed that the three fragments show strong homology to rice PAC and BAC clones that formed a contig representing the short arm of chromosome 8. PCR amplification using the above-mentioned primers on a larger population, derived from a cross between two indica rice varieties, Jhitpiti (resistant parent) and TN1 (susceptible parent), showed that there is a tight linkage between the markers and the Gm8 locus. These markers, therefore, have potential for use in marker-aided selection and pyramiding of Gm8 along with other previously tagged gall midge resistance genes [Gm2, Gm4(t), and Gm7].The nucleotide sequence data reported here will appear in the EMBL, GenBank and DDBJ nucleotide sequence databases under the accession numbers AY545920–AY545923