Rajeev Rathour scite author profile

Using random amplified polymorphic DNA (RAPD) analysis, 250 isolates of Magnaporthe grisea collected from the north‐western Himalayan region were separated into 25 DNA fingerprint groups or lineages. Of these 25 groups, 13 were exclusive to isolates obtained from Himachal Pradesh (HP), five from Uttaranchal and one from Jammu and Kashmir (J & K), India. Seven remaining groups were composed of isolates from different locations and 26 isolates could not be classified. Although RAPD analysis revealed high genetic variability among M. grisea populations from HP and J & K, genetic variation was low in the isolates collected from Uttaranchal. DNA fingerprint groups specific to a particular geographical region were also obtained. Pathogen population consisting of 119 isolates from north‐western Himalayan region has been grouped into 52 pathotypes on the basis of disease reaction on international differential rice lines. Highest frequency of virulence was trapped on the rice line Caloro (Pi−ks) followed by NP125 (Pi−? and K‐60 (Pi−kp) while it was lowest on Tadukan (Pi−ta and/or Pi−ta2) and BL‐1(Pi−b and Pi−sh). Virulence was rare on Fukunishiki (Pi−zs). Rice line Tetep (Pi−kh+?) was found to be highly effective in north‐western Himalayan region as none of the isolate could infect this line. These blast resistant rice lines can be used in resistance breeding for the effective management of rice blast in this region of India.

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Extensive sequence variation in rice blast resistance gene Pi54 makes it broad spectrum in nature

Thakur

Singh

Das

et al. 2015

Front. Plant Sci.

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Rice blast resistant gene, Pi54 cloned from rice line, Tetep, is effective against diverse isolates of Magnaporthe oryzae. In this study, we prospected the allelic variants of the dominant blast resistance gene from a set of 92 rice lines to determine the nucleotide diversity, pattern of its molecular evolution, phylogenetic relationships and evolutionary dynamics, and to develop allele specific markers. High quality sequences were generated for homologs of Pi54 gene. Using comparative sequence analysis, InDels of variable sizes in all the alleles were observed. Profiling of the selected sites of SNP (Single Nucleotide Polymorphism) and amino acids (N sites ≥ 10) exhibited constant frequency distribution of mutational and substitutional sites between the resistance and susceptible rice lines, respectively. A total of 50 new haplotypes based on the nucleotide polymorphism was also identified. A unique haplotype (H_3) was found to be linked to all the resistant alleles isolated from indica rice lines. Unique leucine zipper and tyrosine sulfation sites were identified in the predicted Pi54 proteins. Selection signals were observed in entire coding sequence of resistance alleles, as compared to LRR domains for susceptible alleles. This is a maiden report of extensive variability of Pi54 alleles in different landraces and cultivated varieties, possibly, attributing broad-spectrum resistance to Magnaporthe oryzae. The sequence variation in two consensus region: 163 and 144 bp were used for the development of allele specific DNA markers. Validated markers can be used for the selection and identification of better allele(s) and their introgression in commercial rice cultivars employing marker assisted selection.

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Analysis of Magnaporthe oryzae Genome Reveals a Fungal Effector, Which Is Able to Induce Resistance Response in Transgenic Rice Line Containing Resistance Gene, Pi54

et al. 2016

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Rice blast caused by Magnaporthe oryzae is one of the most important diseases of rice. Pi54, a rice gene that imparts resistance to M. oryzae isolates prevalent in India, was already cloned but its avirulent counterpart in the pathogen was not known. After decoding the whole genome of an avirulent isolate of M. oryzae, we predicted 11440 protein coding genes and then identified four candidate effector proteins which are exclusively expressed in the infectious structure, appresoria. In silico protein modeling followed by interaction analysis between Pi54 protein model and selected four candidate effector proteins models revealed that Mo-01947_9 protein model encoded by a gene located at chromosome 4 of M. oryzae, interacted best at the Leucine Rich Repeat domain of Pi54 protein model. Yeast-two-hybrid analysis showed that Mo-01947_9 protein physically interacts with Pi54 protein. Nicotiana benthamiana leaf infiltration assay confirmed induction of hypersensitive response in the presence of Pi54 gene in a heterologous system. Genetic complementation test also proved that Mo-01947_9 protein induces avirulence response in the pathogen in presence of Pi54 gene. Here, we report identification and cloning of a new fungal effector gene which interacts with blast resistance gene Pi54 in rice.

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Construction of intersubspecific molecular genetic map of lentil based on ISSR, RAPD and SSR markers

Gupta

Verma

Kumar

et al. 2012

J Genet

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Lentil (Lens culinaris ssp. culinaris), is a self-pollinating diploid (2n = 2x = 14), cool-season legume crop and is consumed worldwide as a rich source of protein (~24.0%), largely in vegetarian diets. Here we report development of a genetic linkage map of Lens using 114 F(2) plants derived from the intersubspecific cross between L 830 and ILWL 77. RAPD (random amplified polymorphic DNA) primers revealed more polymorphism than ISSR (intersimple sequence repeat) and SSR (simple sequence repeat) markers. The highest proportion (30.72%) of segregation distortion was observed in RAPD markers. Of the 235 markers (34 SSR, 9 ISSR and 192 RAPD) used in the mapping study, 199 (28 SSRs, 9 ISSRs and 162 RAPDs) were mapped into 11 linkage groups (LGs), varying between 17.3 and 433.8 cM and covering 3843.4 cM, with an average marker spacing of 19.3 cM. Linkage analysis revealed nine major groups with 15 or more markers each and two small LGs with two markers each, and 36 unlinked markers. The study reported assigning of 11 new SSRs on the linkage map. Of the 66 markers with aberrant segregation, 14 were unlinked and the remaining 52 were mapped. ISSR and RAPD markers were found to be useful in map construction and saturation. The current map represents maximum coverage of lentil genome and could be used for identification of QTL regions linked to agronomic traits, and for marker-assisted selection in lentil.

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Rajeev Rathour

Development and evaluation of near-isogenic lines for major blast resistance gene(s) in Basmati rice

RAPD and Pathotype Analyses of Magnaporthe grisea Populations from the north‐western Himalayan Region of India

Extensive sequence variation in rice blast resistance gene Pi54 makes it broad spectrum in nature

Analysis of Magnaporthe oryzae Genome Reveals a Fungal Effector, Which Is Able to Induce Resistance Response in Transgenic Rice Line Containing Resistance Gene, Pi54

Construction of intersubspecific molecular genetic map of lentil based on ISSR, RAPD and SSR markers

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