- Research article
- Open Access
Genetic diversity of the conserved motifs of six bacterial leaf blight resistance genes in a set of rice landraces
BMC Genetics volume 15, Article number: 82 (2014)
Bacterial leaf blight (BLB) caused by the vascular pathogen Xanthomonas oryzae pv. oryzae (Xoo) is one of the most serious diseases leading to crop failure in rice growing countries. A total of 37 resistance genes against Xoo has been identified in rice. Of these, ten BLB resistance genes have been mapped on rice chromosomes, while 6 have been cloned, sequenced and characterized. Diversity analysis at the resistance gene level of this disease is scanty, and the landraces from West Bengal and North Eastern states of India have received little attention so far. The objective of this study was to assess the genetic diversity at conserved domains of 6 BLB resistance genes in a set of 22 rice accessions including landraces and check genotypes collected from the states of Assam, Nagaland, Mizoram and West Bengal.
In this study 34 pairs of primers were designed from conserved domains of 6 BLB resistance genes; Xa1, xa5, Xa21, Xa21(A1), Xa26 and Xa27. The designed primer pairs were used to generate PCR based polymorphic DNA profiles to detect and elucidate the genetic diversity of the six genes in the 22 diverse rice accessions of known disease phenotype. A total of 140 alleles were identified including 41 rare and 26 null alleles. The average polymorphism information content (PIC) value was 0.56/primer pair. The DNA profiles identified each of the rice landraces unequivocally. The amplified polymorphic DNA bands were used to calculate genetic similarity of the rice landraces in all possible pair combinations. The similarity among the rice accessions ranged from 18% to 89% and the dendrogram produced from the similarity values was divided into 2 major clusters. The conserved domains identified within the sequenced rare alleles include Leucine-Rich Repeat, BED-type zinc finger domain, sugar transferase domain and the domain of the carbohydrate esterase 4 superfamily.
This study revealed high genetic diversity at conserved domains of six BLB resistance genes in a set of 22 rice accessions. The inclusion of more genotypes from remote ecological niches and hotspots holds promise for identification of further genetic diversity at the BLB resistance genes.
In rice more than 70 diseases caused by fungi, bacteria, viruses and nematodes are prevalent (Oryza sativa). The most devastating of them are the ones caused by Magnaporthe grisea (rice blast), Xanthomonas oryzae pv. oryzae (bacterial leaf blight, BLB) and Rhizoctonia solani (sheath blight). Improved agricultural practices, nutritional supplements, application of fungicides, bactericides and resistant cultivars had been used for disease control but no durable solution was available due to the breakdown of the resistance by high pathogenic variability. Hence, the search for resistant rice genotypes, particularly among the landraces, is in progress. According to Harlan  the extensive diverse array of rice landraces available worldwide are probable storehouses for novel alleles for many qualitative and quantitative traits. Harlan’s study emphasized that each landrace has certain unique properties or characteristics; such as early maturity, adaptation to particular soil types, resistance or tolerance to biotic and abiotic stresses, and in the end usage of the grains. India is home to many such unique landraces and the ones found in the ecological hotspots of the Indo-Burma region, and the Indian states of West Bengal, Assam, Nagaland, Mizoram and Manipur deserve special mention .
BLB caused by the vascular pathogen Xanthomonas oryzae pv. oryzae (Xoo) is one of the most serious diseases leading to crop failure in rice growing countries including Korea, Taiwan, Philippines, Indonesia, Thailand, India and China. Xanthomonas (from two Greek words; xanthos, meaning ‘yellow’, and monas, meaning ‘entity’) is a large genus of gram-negative and yellow-pigmented bacteria. Xoo enters rice leaf typically through the hydathodes at the leaf margin, multiplies in the intercellular spaces of the underlying epithelial tissue, and moves to the xylem vessels to cause systemic infection [3, 4].
Genes conferring resistance to the major classes of plant pathogens have been isolated from a variety of plant species and are termed ‘R genes’ . Comparison of the structural features and the sequences of the predicted proteins from the cloned ‘R genes’ from various plants have led to the identification of common domains which are conserved and show little variation. These conserved domains can be divided into five broad classes. They are the nucleotide-binding domain (NBD), the leucine rich repeat domain (LRR), the coiled coil domain (CC), the serine/threonine protein kinase domain and the detoxifying enzymes . A total of 38  BLB resistance genes (R genes) have been identified in rice, including Xa1, Xa2, Xa3/Xa26, Xa4, xa5, Xa6, Xa7, xa8, xa9, Xa10, Xa11, Xa12, xa13, Xa14, xa15, Xa16, Xa17, Xa18, xa19, xa20, Xa21, Xa22(t), Xa23, xa24(t), xa25/Xa25(t), Xa25, xa26(t), Xa27, xa28(t), Xa29(t), Xa30 (t), xa31(t), Xa32(t), xa33(t), xa34(t), Xa35(t), Xa36(t). The recessive resistance genes include xa5, xa8, xa9, xa13, xa15, xa19, xa20, xa24, xa25/Xa25(t), xa26(t), xa28(t), xa31(t), xa33(t), and xa34(t). Of the 37, 10 BLB resistance (R) genes have been mapped on rice chromosomes 4 (Xa1, Xa2, Xa12, Xa14 and Xa25), chromosome 5 (xa5), chromosome 6 (Xa7), chromosome 8 (xa13), and chromosome 11 (Xa3, Xa4, Xa10, Xa21, Xa22, and Xa23). The chromosomal locations for the rest of the BLB resistance genes still remain elusive. These R genes are known to act in a gene-for-gene manner and are the main sources for genetic improvement of rice for resistance to Xoo. Ten of the recessive R genes; xa5, xa8, xa13, xa24, xa26, xa28 and xa32 occur naturally and confer race-specific resistance. The other 3, xa15, xa19 and xa20, were created by mutagenesis and each confers a wide spectrum of resistance to Xoo[11, 13, 15].
Six BLB resistance genes, Xa1, xa5, Xa21, Xa21(A1), Xa26 and Xa27, have been cloned, sequenced and characterized. In 1967, Sakaguchi  identified Xa1 conforming a high level of specific resistance to race 1 strains of Xoo in Japan and mapped it on rice chromosome 4. The gene xa5 is a naturally occurring mutation that is most commonly found in the Aus-Boro group of rice varieties from the Bangladesh region of Asia [7, 17]. The predicted protein product of Xa21 carries LRRs in the extracellular region and a serine/threonine kinase domain in the cytoplasm . Xa21 is a member of a multigene family located on rice chromosome 11 [18, 19]. Seven Xa21 gene family members, designated A1, A2, B, C, D, E, and F, were cloned and grouped into two classes based on DNA sequence similarity . Xa26 is a dominant gene coding for a LRR receptor kinase protein. It is mapped to the long arm of chromosome 11 [11, 20] and was found in cultivar Mingui 63 which showed resistance against a number of Xoo strains both at seedling and at adult stage suggesting that it was not developmentally regulated . The Xa27 locus of rice conferred resistance to diverse strains of Xoo, including PXO99A, a strain isolated from rice variety IRBB27 by map-based cloning. Xa27 is an intron-less gene and encodes a protein of 113 amino acids.
Natural selection in the ecological niches of the world has generated landraces that are highly diverse for various quality, quantity and disease resistance traits controlling loci. It is important to identify and maintain this polymorphism to widen the genetic base of the commercially cultivated varieties and to reduce pathogen pressure. According to Glaszman et al.  study of local sequence variation reveals the multiple examples of mutation that have taken place due to adaptation towards specific drifts and selection pressure. This adaptive neo diversity superimposes on the ancestral diversity inherited from wild relatives and forms an important section in the passport data of various accessions. It is a tedious task to put the existing natural variation to commercial use. As a step towards that process Nordborg and Weigel  suggested the use of genome-wide association (GWA) mapping which associates the phenotype of interest to DNA sequence variation present in an individual’s genome determined by polymorphism at various loci. GWA mapping gives much higher resolution than linkage mapping because they involve studying associations in natural populations and reflect adaptive recombination events. This kind of mapping is very useful in self fertilized species like A. thaliana and rice . Further, in view of the challenge of assessing the diversity in large germplasm collections, the core collection concept was developed wherein diversity analysis will first be concentrated on a representative manageable sample before extending the study to a broad range of accessions . Such programs have been undertaken for rice and chickpea. In accordance with such postulates the objective of this study is to analyze a small set of phenotypically variable rice accessions from BLB disease hotspot for getting a birds-eye view of the existing diversity in 6 BLB resistant gene loci of those accessions.
Reports of diversity analysis of the BLB resistance genes are available. Ullah et al., identified the presence of the genes Xa4, xa5, Xa7, and xa13 in 52 basmati landraces and five basmati cultivars using Polymerase Chain Reaction (PCR) based methods. They also found that the gene Xa7 was most prevalent among the cultivars and landraces while the genes xa5 and xa13 were confined to landraces only. Ten basmati landraces from their study had multiple resistance genes. Arif et al., identified the BLB resistance gene Xa4 in 49 Pakistani rice lines. Lee et al., identified three rice cultivars with resistance to various Phillipino Xoo strains. The cultivar Nep Bha Bong had a new recessive gene, designated as xa26(t) for moderate resistance to races 1, 2, and 3 and resistance to race 5. The cultivar Arai Raj had a dominant gene designated as Xa27(t) for resistance to race 2. The cultivar Lota Sail had a recessive gene designated as xa28(t) for resistance to race 2. Bimolata  analyzed the sequence variation in the functionally important domains of Xa27 across the Oryza species and found synonymous and non-synonymous mutations in addition to a number of InDels in non-coding regions of the gene. To the best of our knowledge, there is no report available on diversity of BLB resistance loci of rice landraces from the Indian states of Assam, Arunachal Pradesh, Nagaland, Mizoram, Manipur, Tripura and West Bengal.
In this study 34 pairs of primers were designed from conserved domains of the six BLB resistance genes; Xa1, Xa5, Xa21, Xa21(A1), Xa26 and Xa27. The designed primer pairs were used to generate PCR based polymorphic DNA profiles to detect and elucidate the genetic diversity of the six genes in the 22 rice accessions collected from West Bengal and the North Eastern States of India.
A total of 22 rice genotypes, including landraces and check genotypes, were collected from rice research stations in India. The names of the accessions, source, category and disease phenotype are given in Table 1.
Designing primers from conserved domains of 6 BLB resistance genes
Thirty four pairs of primers were designed from publicly available sequences (NCBI) of conserved domains of 6 BLB resistance genes using the software BatchPrimer3 (http://probes.pw.usda.gov/batchprimer3). The conserved domains are: P loop, kinase 2, trans-membrane domain and LRR domain of the Xa1 gene; TF IIA domain of the xa5 gene; receptor kinase domain of the Xa26 gene; the total DNA sequence of the Xa27 gene; signal, LRR, charged and kinase domain of the Xa21 gene; and LRR, SNAP O11 and kinase domain of the Xa21(A1) gene. These primer pairs were named according to the initials of the first author and the corresponding author and were numbered from BDTG1 to BDTG34. The primer pairs were designed only from the exons such that the length of the amplified products was limited to 500 to 700 base pairs. Details of the primer names, respective resistance genes, representing protein domains, original genotypes from which the resistance genes were identified, number of exons and introns, chromosomal location in base pairs (bp) of each primer pairs and the expected length of the amplification product from the original genotype in base pairs (bp) are given in Table 2.
Isolation of rice genomic DNA and PCR amplification
Total genomic DNA was isolated from ten 3 day-old rice seedlings using the method of Walbot  with modifications. The DNA was PCR amplified using a protocol standardized in our lab and used in our previous paper .
Polyacrylamide gel electrophoresis and allele scoring
The PCR products were resolved in 6% polyacrylamide gel using the procedure described by Sambrook et al. . The gel staining, visualization and assignment of alleles were done according to protocols in our previous paper . Null alleles were assigned when no amplification product was generated . When an allele was found in less than 5% of the germplasms under study, it was designated as rare .
Calculation of polymorphism information content (PIC) value
The polymorphism information content (PIC) value for the primer pairs was calculated using the formula given by Anderson et al. for self pollinated species
where Pij is the frequency of the jth allele for the ith marker.
Genetic diversity analysis using PCR amplification profiles
A genetic similarity matrix between all possible combinations of pairs of rice accessions was made using Jaccard’s co-efficient  and the NTSYS-pc software package, version 2.02e, . This similarity matrix was used to make a phylogenetic tree using the Unweighted Pair-Group Method of Arithmetic average (UPGMA) and Neighbor-Joining (NJoin) module of the NTSYS-pc. Support for clusters was evaluated by bootstrap analysis using WinBoot software  through generating 1,000 samples by re-sampling with replacement of characters within the combined 1/0 data matrix.
Sequencing and analysis of rare alleles
The DNA was eluted from the bands of rare alleles using QIAquick Gel Extraction Kit following manufacturer’s protocol. The eluted DNA was sequenced through outsourcing and the sequences were submitted to NCBI. For finding the homology and conserved domains, the sequences were BLAST  searched against the non-redundant database of NCBI using default parameters. Apart from NCBI BLAST, homology search for the obtained sequences were done using the “blastn” option of the Rice Annotation Database (http://rice.plantbiology.msu.edu).
Analysis of PCR profiles
The summary of the data of the PCR profiles of the 22 accessions using the 34 pairs of primers is given in Table 3. All the 34 primer pairs produced polymorphic profiles and a total of 140 alleles were identified including 41 rare alleles. There were no unique alleles detected. The number of alleles ranged from 2 to 8 with an average of 4.06 alleles/primer pair. The primer pairs amplifying various regions of the LRR domain (Table 2) on an average produced 4.6 alleles/primer pair. Primer pairs amplifying the regions of kinase domain on an average produced 3.8 alleles/primer pair.
The PIC value ranged from 0.16 for the least informative primer pair BDTG1 to 0.79 for the most informative primer pairs BDTG18, BDTG26 and BDTG29. The average PIC value was 0.56/primer pair.
Diversity in the six loci in this set of rice accession
The diversity generated by the 34 primer pairs in this set of rice accession is given in Additional file 1: Table S1. Briefly the highest variation was found in the locus Xa21(A1) between 4802 bp to 5082 bp (exon1, LRR domain, BDTG26) and between 5763 bp to 6173 bp (exon 1, LRR domain, BDTG29); and in the Xa26 locus between 4574 bp to 5141 bp (exon1, BDTG18), producing 8 alleles each. Three regions in the locus Xa21, from 8 bp to 208 bp (exon 1, the Signal domain, BDTG20), from 260 bp to 760 bp (exon 2, the LRR domain, BDTG21) and from 1279 bp to 1880 bp (exon 2, the LRR domain, BDTG23) produced 7 alleles each. Although the Xa27 locus was small, 392 bp long (1518 bp to 1909 bp), the primer pairs BDTG19 generated 6 alleles including 3 rare 2 null alleles. The next most variable region was in the Xa1 locus between 27182 bp to 27917 bp (exon 4, LRR domain, BDTG10), which produced 5 alleles. The region of TFIIA domain from 406048 bp to 406306 bp of locus xa5 (exon1, BDTG 11) produced 4 alleles including one rare allele and one null allele. The other most variable regions identified within the different loci are given in Additional file 1: Table S1.
Genetic diversity within the different categories of landraces
The West Bengal accessions produced a total of 107 alleles with an average of 3.15 alleles/primer pair. In this group, the highest number of alleles was generated by the primer pair BDTG23, while only one allele each was produced by BDTG6 and BDTG31. The North Eastern accessions produced a total of 100 alleles with an average of 2.94 alleles/primer pair. While the highest number of 6 alleles was generated by BDTG29, only 1 allele each was produced by BDTG8 and BDTG26. The check varieties comprised of one resistant and one susceptible accession. Out of the 41 rare alleles, 8 were produced by the resistant West Bengal landrace Bhasamanik and 7 each were produced by the resistant landraces Raghusail and Bangladeshi Patnai. Four rare alleles were identified in the Assamese aromatic landrace Lal binni and 2 rare alleles each were identified in the landraces Aijong, IC524526, IC524502 and Gobindobhog.
Dendrogram from the genetic similarity values
In the dendrogram the similarity between the rice accessions ranged from 18% to 89% and on this basis they were divided into 2 major clusters A and B (Figure 1). Cluster A separated out at 18% level of similarity and consisted of Raghusail and Bhasamanik, both of which were resistant accessions from West Bengal. Cluster B was subdivided into 4 different sub clusters. Cluster 1 segregated out at 53% level of similarity and included the North Eastern accessions Aijong, Boro Chhaiyamora, IC524502, IC524526 and Lal Binni along with the West Bengal accession Gobindobhog. All the accessions in cluster 1 were BLB susceptible. Cluster 2 segregated at 28.8% level of similarity and included the West Bengal accessions Dudherswar, Bangladeshi Patnai, Talmari, Bangalaxmi and Taraori Basmati, all of which were susceptible. Cluster 3 separated out at 28% level of similarity and consisted of Morianghou, Kala boro dhan, Buhrimtui and Bhu from the North Eastern States along with Chamormoni – an accession from West Bengal. Cluster 4 consisted of the accessions Pusa Basmati 1, the susceptible check TN1, Kataribhog - a resistant accession from West Bengal and IR72 - a resistant check.
Homology searches for the sequences of the rare alleles
A total of forty one rare alleles were sequenced. Of these, 40 were submitted to and were assigned accession numbers by NCBI. The accession numbers of the sequences, details of sequence homology, and the details of the conserved domains corresponding to each sequence is given in Table 4. Fifteen of the sequences were from the North Eastern accessions and 25 sequences were from the West Bengal accessions. BLAST searches using the NCBI database revealed that six rare alleles from the North East were homologous to sequences of BLB resistance genes of Oryza sativa japonica. Three of the rare alleles were homologous with sequences of the Xa21 gene of O. longistaminata. Two rare alleles were homologous to sequences of Xa1 and Xa21(A1) gene of O. sativa indica and one rare allele each was homologous to the Xa21 gene sequence from O. rufipogon and Xa27 gene sequence of O. officinalis ecotype IC203740. The rare alleles from HR806765 and JM426578 from the North Eastern landraces Buhrimtui and Aijong respectively did not show any homology to the existing database.
Out of the 25 rare alleles from the West Bengal landraces, Raghusail and Bhasamanik contributed 8 rare alleles each and Bangladeshi Patnai contributed 7 alleles. Eight rare alleles were homologous to sequences from O. longistaminata and 7 rare alleles were homologous to O. sativa indica sequences from the NCBI database. Five rare alleles each were homologous to sequences of O. rufipogon and O. sativa indica.
Results of homology search using the Rice Genome Annotation Project (RGAP) Database are given in Table 5. The name of the locus which produced the most significant match, description of the matched locus, E-value and details of the Pfam hits are shown in the table. According to this database most of the rare alleles were homologous to sequences of receptor kinase like proteins.
Identification of conserved domains and retrotransposons from the DNA sequences of rare alleles using NCBI and rice genome annotation project database
A total of 23 conserved domains were identified from the 40 rare alleles. The details of homology search and the conserved domain corresponding to the sequence of each rare allele is given in Table 4. Fifteen of the domains were homologous to LRRs. These domains included receptor like kinases (found in 9 sequences), LRR N-terminal domains (found in 4 sequences) and Leucine-Rich Repeats ribonuclease inhibitor (RI)-like subfamily (found in 2 sequences).
The sequences with accession numbers HR575926 and HR575924 (both derived from landrace Raghusail) and HR806763 (derived from landrace IC524526) were homologous to the NB-ARC domain-containing protein having a Pfam hit with BED zinc finger domain (zf-BED). According to Arvind  BED-type zinc-finger domain [named after BAEF (boundary element-associated factor)  and DREF (DNA replication-related element-binding factor),  is found in the Oryza Xa1 gene. HR614233 and HR575927 were significantly homologous to transcription initiation factor IIA gamma chain, having a Pfam hit with TFIIA_gamma_N. Another sequence HR614234 was homologous to aspartic proteinase nepenthesin-1 precursor having a Pfam hit with Asp or Aspartic proteases family. Sequence JM426580 was significantly homologous to mRNA sequence of the gene Xa27 of Oryza sativa indica. The sequences HR806767 and HR806746 were found to have conserved domains homologous to sugar transferase, and NodB domain of the carbohydrate esterase 4 superfamily.
Conserved domain searches using the Rice Annotation Database revealed the presence of mobile DNA elements within the sequence of 4 of the rare alleles. HQ832768, the sequence of a rare allele from the West landrace Bhasamanik was homologous to an unclassified retrotransposon protein having a Pfam hit of Plant_tran or plant tranposases. The sequence HR806765 from the Mizoram landrace Buhrimtui showed homology with a putative transposon protein, CACTA, En/Spm sub-class of Oryza sativa subsp. japonica. According to UniProt database this transposon protein has a molecular function of helicase and hydrolase. JM426578 from the Assam landrace Aijong was significantly homologous to a putative retrotransposon protein of the Ty3-gypsy type. HR806755 from the Assam landrace Lal Binni was significantly homologous to a putative unclassified retrotransposon protein.
The Eastern and North Eastern regions of India are one of the richest reserves of bio-diversity in the country . The inherent variation in the ecotypes of rice, spontaneously evolved in the Eastern State of West Bengal was high enough for scientists to group them as Oryza sativa var. benghalensis, at one time . DNA-based markers like SSR and RAPD have been used extensively for the study of such inherent genetic diversity in rice. The results of these studies were also used for unambiguous identification of germplasm and their protection under the trade related intellectual property rights (TRIPS) of the World Trade Organization (WTO). The accessions used in this study were selected from a larger collection to include as much variability as possible based on the agro-morphological data and SSR polymorphism analysis done previously in our laboratory [28, 42]. As a follow up of those studies, we aim to extend the search for genetic variability specific to various quality traits and disease resistance abilities. Information on the diversity of disease resistance loci is important to the plant breeders for the identification of diverse donors with major genes and partial resistance. In this preliminary assessment we have tried to find the genetic diversity within six cloned BLB resistance genes in a set of 22 diverse rice accessions using PCR based methods. Even though the sample size is small (22 accessions) it includes accessions of rice varieties from 5 Indian states both aromatic and non-aromatic along with traditional and evolved basmatis and checks.
The PCR profiles of all the 34 primer pairs were clear and consistent. Stutter bands, which were minor products amplified in PCR that has lower intensity than the main allele and normally lacks or has extra repeat units were also present in the profiles of most of the primer pairs . The null alleles were probably due to mutations in the binding region of one or both of the primers, thereby inhibiting primer annealing . The presence of 140 alleles in the 22 accessions indicates high genetic diversity within the 6 BLB resistance gene loci. Analyzing the phenotype-genotype association after actual disease inoculation is requisite for confirming whether the identified rare alleles have any impact on BLB resistance or they are new alleles for BLB resistance. Moreover, the sample size being 22 accessions only, an identified rare allele might no longer be rare after the inclusion of more accessions.
It can be seen from the dendrogram that there was no state-wise or geographical segregation of the accessions based on the obtained polymorphism data. However cluster 1 and 3 consists mostly of the accessions from the North Eastern States. There was some degree of segregation based on whether the accessions were resistant or susceptible. The two resistant landraces from West Bengal, Raghusail and Bhasamanik segregated into a separate major cluster (major cluster A). These two landraces were about 39% similar amongst themselves. The dendrogram also shows instances where susceptible and resistant cultivars have been grouped together. The resistant accessions Kataribhog and IR72 have 89% similarity amongst themselves and they are grouped into cluster 4 along with two susceptible accessions TN1 and Pusa Basmati 1. Another resistant cultivar Bangladeshi patnai is 42% similar to a susceptible, but very popular table rice variety, Dudherswar. Future similar studies incorporating more accessions will confirm whether the alleles generated by the designed primers used here are actually able to segregate accessions on the basis of disease phenotype. Future efforts should concentrate on DNA sequencing, Multiple Sequence alignment and association mapping of all the involved alleles to identify possible linkages between the DNA sequence and the disease phenotype. For improving disease resistance of the aromatic accessions parents may be chosen from major cluster A and B.
According to Zhao et al.  most of the knowledge about the genetic architecture of complex traits in rice is based on traditional quantitative trait locus (QTL) linkage mapping using bi-parental populations, which though informative but are not suitable to investigate the genomic potential and tremendous phenotypic variation of the more than 120,000 accessions available in public germplasm repositories. This can only be achieved by documentation of genomic variation at specific loci controlling complex traits using specific genomic region based primers rather than random primers. This variation then has to be coupled with association mapping, a method popularly known as GWA. The information regarding the diversity of domains of the 6 BLB resistant loci obtained in this study is the first step towards such mapping programs. Rather than sequencing all the alleles obtained, only the rare alleles were sequenced in this study. Hence we could not establish any association between the DNA sequence and the resistant and susceptible accessions. For this sequencing of all the alleles and its correlation with disease phenotype are required and these are areas open for future investigation. If such associations can be found, then those will be the forerunner of GWA mapping for BLB resistance loci. In addition to the usual domains like LRR, TFIIA and BED-type zinc-finger, homologies to other conserved domains were also found in this study. The sequence HR806767 was homologous to a sugar transferase domain. Members of sugar transferase family are similar to the pfam00534 Glycosyl transferases group 1 domain. Glycosyltransferases can transfer single or multiple activated sugars to a range of plant molecules, resulting in the glycosylation of plant compounds and plays a key role in in the regulation of plant growth, development and in defense responses to stress environments . Sequence HR806746 is homologous to a Catalytic NodB homology domain of the carbohydrate esterase 4 superfamily. This family catalyzes the N- or O-deacetylation of substrates such as acetylated chitin, peptidoglycan, and acetylated xylan, respectively . The sequence HR614234 is homologous to aspartic proteinase nepenthesin-1 precursor. The Oryza sativa constitutive disease resistance 1 (OsCDR1) gene product is an aspartic proteinase that has been implicated in disease resistance signaling. This apoplastic enzyme is a member of the group of ‘atypical’ plant aspartic proteinases . These unusual conserved domains within the rare alleles can be the result of local adaptation. Evaluation of the exact role of these unusual motifs in BLB resistance could be done with the help of disease inoculation and assessment of the disease phenotype. However that was beyond the scope of this study and has been left for future studies.
Transposable elements (TEs) were detected in the DNA sequence of 4 rare alleles. Transposable elements (TEs) are fundamental role players in the variation and adaptive evolution of plant genomes [48–50]. Grass genomes are reported to have active retrotransposons . LTR retrotransposons constitute a major portion of the rice genome . Retrotansposons are activated during stress, wounding and pathogen attack [53, 54]. For example transcription of the tobacco retrotransposon Tnt1 could be induced by pathogens and microbial elicitors, as well as by abiotic factors, [55–57]. Moreover Tnt1 insertion could change host gene splicing . A group of LTR retrotransposons was found near the genes encoding the NPR1 disease resistance-activating factor and a heat-shock-factor-(HSF-) like protein in sugarbeet hybrid US H20 . The TEs in this study were found mostly in landraces from the North East or from West Bengal BLB resistant landrace. The probable role of these identified tranaposable elements in this study are yet to be investigated.
As the name implies, conserved domains of genes are thought to possess little variation. However, this study finds that there is high genetic variability even within the conserved domains of BLB resistance genes in a small set of 22 rice accessions. Environmental stresses including high rainfall, humidity, varied topography and altitude, heavy natural selection pressures of diseases and pests, together with introductions over time and space from adjoining countries like Bhutan, China, Myanmar and Bangladesh; introgression from the wild and weedy relatives, tribal preferences and rituals have been instrumental in the development of this diversity . The inclusion of more genotypes from remote ecological niches and hotspots holds more promise for further allele mining. Future studies should concentrate on DNA sequencing of all the alleles obtained in this study to bring out possible differences between susceptible and resistance accessions. Association mapping after disease inoculation will help to bring out the linkage between the alleles and disease phenotype. Such kind of mapping will be the stepping stone towards genome wide association mapping for BLB resistant loci. Search for transposable elements in the BLB resistance gene loci of the North eastern and resistant rice accessions, and elucidation of their function should form another area of interest.
Harlan JR: Crops and Man. 1975, Madison, Wisconsin: American Society of Agronomy and Crop Science Society of America
Hore DK: Rice diversity collection, conservation and management in northeastern India. Genet Resour Crop Evol. 2005, 52: 1129-1140.
Noda T, Kaku H: Growth of Xanthomonas oryzae pv. oryzae in planta and in guttation fluid of rice. Ann Phytopathol Soc Jpn. 1999, 65: 9-14.
Ou SH: Rice diseases. kew, surrey: commonwealth agricultural bureau: family of type III effectors are major virulence determinants in bacterial blight disease of rice. Mol Plant-Microbe Interact. 1985, 17: 1192-1200.
Hammond-Kosack KE, Jones JDG: Plant disease resistance genes. Annu Rev Plant Physiol Plant Mol Biol. 1997, 48: 575-607.
Khan MA, Naeem M, Iqbal M: Breeding approaches for bacterial leaf blight resistance in rice (Oryza sativa L.), current status and future directions. Eur J Plant Pathol. 2014, 139: 27-37.
Petpisit V, Khush GS, Kauffman HE: Inheritance to bacterial blight in rice. Crop Sci. 1977, 17: 551-554.
Singh K, Vikal Y, Singh S, Leung H, Dhaliwal HS, Khush GS: Mapping of bacterial blight resistance gene xa8 using microsatellite markers. Rice Genet Newsl. 2002, 19: 94-96.
Ogawa T, Lin L, Tabien RE, Khush GS: A new recessive gene for resistance to bacterial blight of rice. Rice Genet Newsl. 1987, 4: 98-100.
Khush GS, Angeles ER: A new gene for resistance to race 6 of bacterial blight in rice, Oryza sativa L. Rice Genet Newsl. 1999, 16: 92-93.
Lee KS, Rasabandith S, Angeles ER, Khush GS: Inheritance of resistance to bacterial blight in 21 cultivars of rice. Phytopathology. 2003, 93: 147-152.
Ruan HH, Yan CQ, An DR, Liu RH, Chen JP: Identifying and mapping new gene xa32 (t) for resistance to bacterial blight (Xanthomonas oryzae pv. oryzae, Xoo) from Oryzae meyeriana L. Acta Agricult Boreali-occidentalis Sin. 2008, 17: 170-174.
Ogawa T: Monitoring race distribution and identification of genes for resistance to bacterial leaf blight. Rice Genetics III, Proceeding of the Third International Rice Genetics Symposium. Edited by: Khush GS. 1996, Manila, Philippines: International Rice Research Institute, P.O. Box 933, 456-459.
Taura S, Ogawa T, Yoshimura A, Ikeda R, Iwata N: Identification of a recessive resistance gene to rice bacterial blight of mutant line XM6, Oryzae sativa L. Jpn J Breed. 1992, 42: 7-13.
Chen S, Huang ZH, Zeng LX, Yang JY, Liu QG, Zhu XY: High resolution mapping and gene prediction of Xanthomonas oryzae pv. oryzae resistance gene Xa7. Mol Breed. 2008, 22: 433-441.
Sakaguchi S: Linkage studies on the resistance to bacterial leaf blight, Xanthomonas oryzae (Uyeda et Ishiyama) Dowson, in rice. Bull Natl Inst Agr Sci Ser. 1967, D16: 1-18. in Japanese with English summary
Garris AJ, McCouch SR, Kresovich S: Population structure and its effect on haplotype diversity and linkage disequilibrium surrounding the xa5 locus of rice (Oryza sativa L.). Genetics. 2003, 165: 759-769.
Song WY, Wang GL, Chen LL, Kim HS, Pi LY, Holsten T, Gardner J, Wang B, Zhai WX, Zhu LH, Fauquet C, Ronald P: A receptor kinase-like protein encoded by the rice disease resistance gene, Xa21. Science. 1995, 270: 1804-1806.
Ronald PC, Albano B, Tabien R, Abenes L, Wu K: Genetic and physical analysis of the rice bacterial blight disease resistance locus, Xa21. Mol Gen Genet. 1992, 236: 113-120.
Yang Z, Sun X, Wang S, Zhang Q: Genetic and physical mapping of a new gene for bacterial blight resistance in rice. Theor Appl Genet. 2003, 106: 1467-1472.
Glaszmann JC, Kilian B, Upadhyaya HD, Varshney RK: Accessing genetic diversity for crop improvement. Curr Opin Plant Biol. 2010, 13: 1-7.
Nordborg M, Weigel D: Next-generation genetics in plants. Nature. 2008, 456: 11-
Frankel OH: Genetic perspective of germplasm conservation. Genetic Manipulations: Impact on Man and Society. Edited by: Arber W, Llimensee K, Peacock WJ, Stralinger P. 1984, Cambridge: Cambridge University Press, 161-170.
Ullah I, Jamil S, Iqbal MZ, Shaheen HL, Hasni SM, Jabeen S, Mehmood A, Akhter M: Detection of bacterial blight resistance genes in basmati rice landraces. Mol Res. 2012, 11 (3): 1960-1966.
Arif M, Jaffar M, Babar M, Munir A, Sheikh MA, Kousar S, Arif A, Zafar Y: Identification of bacterial blight resistance genes Xa4 in Pakistani rice germplasm using PCR. Afr J Biotechnol. 2008, 7 (5): 541-545.
Bimolata W, Kumar A, Sundaram RM, Laha GS, Qureshi IA, Reddy GA, Ghazi IA: Analysis of nucleotide diversity among alleles of the major bacterial blight resistance gene Xa27 in cultivars of rice (Oryza sativa) and its wild relatives. Planta. 2013, 238 (2): 293-305.
Walbot V: Preparation of DNA from single rice seedling. Rice Genet Newsl. 1988, 5: 149-151.
Das B, Sengupta S, Parida SK, Roy B, Ghosh M, Prasad M, Ghose TK: Genetic diversity and population structure of rice landraces from Eastern and North Eastern States of India. BMC Genet. 2013, 14: 71-
Sambrook J, Fritsch EF, Maniatis T: Molecular cloning: A laboratory manual. 1989, New York: Cold Spring Harbour Laboratory Press, 2
Callen DF, Thompson AD, Shen Y, Phillips HA, Richards RI, Mulley JC, Sutherland GR: Incidence and origin of “null” alleles in the (AC) n microsatellite markers. Am J HumGenet. 1993, 52: 922-927.
Jain S, Jain RK, McCouch SR: Genetic analysis of Indian aromatic and quality rice (Oryza sativa L.) germplasm using panels of fluorescently-labeled microsatellite markers. Theor Appl Genet. 2004, 109: 965-977.
Anderson PA, Lawrence GJ, Morrish BC, Ayliffe MA, Finnegan EJ, Ellis JG: Inactivation of the Flax rust resistance gene M associated with loss of a repeated unit within the leucine rich repeat coding region. Plant Cell. 1997, 9: 641-651.
Jaccard P: Nouvelle recherches sur la distribution florale. Bulletin de la Socie´te´ Vaudoise des Sciences Naturelles. 1908, 44: 223-270.
Rohlf FJ: NTSYS-pc. Numerical taxonomy and multivariance analysis system version 2.02e. 1997, New York, USA: Exeter Software, http://www.exetersoftware.com/cat/ntsyspc/ntsyspc.html,
Yap IP, Nelson R: IPRI Discussion Paper series. Win Boot: A programm for performing boot strap analysis of binary data to determine the confidence limits of UPGMA-based dendrograms. 1995
Altschul SF, Madden TL, Schaffer AA, Zhang J, Zhang Z, Miller W, Lipman DJ: Gapped BLAST and PSI-BLAST: a new generation of protein database search programs. Nucleic Acids Res. 1997, 25: 3389-3402.
Aravind L: The BED finger, a novel DNA-binding domain in chromatin-boundary-element-binding proteins and transposases. Trends Biochem Sci. 2000, 25 (9): 421-423.
Hart CM, Cuvier O, Laemmli UK: Evidence for an antagonistic relationship between the boundary element-associated factor BEAF and the transcription factor DREF. Chromosoma. 1999, 108 (6): 375-383.
Matsukage A, Hirose F, Yoo MA, Yamaguchi M: The DRE/DREF transcriptional regulatory system: a master key for cell proliferation. Biochim Biophys Acta. 2008, 1779: 81-89.
Hore DK, Sharma BD: Wild Rice genetic resources of North-east India. Indian J. Pl. Genet. Resour. 1993b, 6: 27-32.
Chatterjee SD, Adhikari B, Ghosh A, Ahmed J, Neogi SB, Pandey N: The rice biodiversity in West Bengal. 2008, Department of Agriculture, West Bengal: Govt. of West Bengal, 50-
Das B, Sengupta S, Ghosh M, Ghose TK: Assessment of diversity amongst a set of aromatic rice genotypes from India. Int J Biodive Conserv. 2012, 4 (5): 206-218.
Walsh PS, Fildes NJ, Reynolds R: Sequence analysis and characterization of stutter products at the tetranucleotide repeat locus vWA. Nucleic Acids Res. 1996, 24: 2807-2812.
Zhao K, Tung CW, Eizenga GC, Wright MH, Ali ML, Price AH, Norton GJ, Islam MR, Reynolds A, Mezey J, McClung AM, Bustamante CD, McCouch SR: Genome-wide association mapping reveals a rich genetic architecture of complex traits in Oryza sativa. Nature. 2011, 2 (467): 1-10.
Wang J, Hou BK: Glycosyltransferases: key players involved in the modification of plant secondary metabolites. Front Biol China. 2009, 4: 39-46.
Millward-Sadler SJ, Davidson K, Hazlewood GP, Black GW, Gilbert HJ, Clark JH: Novel cellulose-binding domains, NodB homologues and conserved modular architecture in xylanases from the aerobic soil bacteria Pseudomonas fluorescens subsp. cellulosa and Celivibrio mixtus. Biochem J. 1995, 312: 39-48.
Prasad BD, Creissen G, Lamb C, Chattoo BB: Heterologous expression and characterization of recombinant OsCDR1, a rice aspartic proteinase involved in disease resistance. Protein Expr Purif. 2010, 72: 169-174.
McClintock B: The significance of responses of the genome to challenge. Science. 1984, 226: 792-801.
McDonald JF: Transposable elements:-possible catalysts of organismic evolution. Trends Ecol Evol. 1995, 10: 123-126.
Kidwell MG, Lisch D: Transposable elements as sources of variation in animals and plants. Proc Natl Acad Sci U S A. 1997, 94: 7704-7711.
Vicient CM, Jääskeläinen MJ, Kalendar R, Schulman AH: Active retrotransposons are a common feature of grass genomes. Plant Physiol March. 2001, 125 (3): 1283-1292.
Matsumoto T, Wu J, Kanamori H, Katayose Y, Fujisawa M, Namiki N, Mizuno H, Yamamoto K, Antonio BA, Baba T, Sakata K, Nagamura Y, Aoki H, Arikawa K, Arita K, Bito T, Chiden Y, Fujitsuka N, Fukunaka R, Hamada M, Harada C, Hayashi A, Hijishita S, Honda M, Hosokawa S, Ichikawa Y, Idonuma A, Iijima M, Ikeda M, Ikeno M, et al: The map-based sequence of rice genome. Nature. 2005, 436: 793-800.
Wessler SR: Turned on by stress: plant retrotransposons. Curr Biol. 1996, 6: 959-961.
Grandbastien MA: Activation of retrotransposons under stress conditions. Trends Plant Sci. 1998, 3: 181-187.
Pouteau S, Boccara M, Grandbastien MA: Microbial elicitors of plant defense responses activate transcription of a retrotransposon. Plant J. 1994, 5: 535-542.
Mhiri C, Morel JB, Vernhettes S, Casacuberta JM, Lucas H, Grandbastien MA: The promoter of the tobacco Tnt1 retrotransposon is induced by wounding and by abiotic stress. Plant Mol Biol. 1997, 33: 257-266.
Vernhettes S, Grandbastien MA, Casacuberta JM: In vivo characterization of transcriptional regulatory sequences involved in the defence-associated expression of the tobacco retrotransposon Tnt1. Plant Mol Biol. 1997, 35: 673-679.
Leprinc AS, Grandbastien MA, Christian M: Retrotransposons of the Tnt1B family are mobile in Nicotiana plumbaginifolia and can induce alternative splicing of the host gene upon insertion. Plant Mol Biol. 2001, 47: 533-541.
Kuykendall D, Shao J, Trimmer K: A nest of LTR Retrotransposons adjacent the disease resistance-priming gene NPR1 in Beta vulgaris L. U.S. Hybrid H20. Int J Plant Genomics. 2009, 576742-
Yang GP, Maroof MAS, Xu CG, Zang Q, Baiyashev RM: Comparative analysis of microsatellite DNA polymorphism in landraces and cultivars of rice. Mol Gen Genet. 1994, 245: 187-194.
The authors wish to thank Assam Agriculture University, Agricultural Training Centre, Fulia, Rice Research Station, Chinsurah, National Bureau of Plant Genetic Resources and State Agricultural Research Farm, Kashipur for contributing the rice accessions. They also wish to thank the Department of Science and Technology for providing the research funding through Bose Institute and for providing the fellowship to Basabdatta Das. Thanks are also due to the University of Calcutta for providing fellowship to Samik Sengupta. Authors kindly acknowledge Muthamilarasan M of NIPGR, New Delhi for critically reading the manuscript.
The authors declare that they do not have any competing interests.
BD did all the experiments pertaining to DNA extraction, PCR, PAGE, collected data and was involved in data analysis and drafting of the manuscript. SS procured the rice accessions from various repositories of the North Eastern States, did some of the experimentation pertaining to PCR and PAGE and helped with data collection and analysis and revision of the manuscript. MP did the bootstrap analysis and helped in drafting of the manuscript. TKG was involved with the conception of the work and gave the final approval to the version of the manuscript that is being sent for consideration for publication. All authors read and approved the final manuscript.
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Das, B., Sengupta, S., Prasad, M. et al. Genetic diversity of the conserved motifs of six bacterial leaf blight resistance genes in a set of rice landraces. BMC Genet 15, 82 (2014). https://doi.org/10.1186/1471-2156-15-82
- Genetic diversity
- BLB resistance
- DNA markers
- Indian landraces