Jyoti Kumari scite author profile

A comprehensive germplasm evaluation study of wheat accessions conserved in the Indian National Genebank was conducted to identify sources of rust and spot blotch resistance. Genebank accessions comprising three species of wheat–Triticum aestivum, T. durum and T. dicoccum were screened sequentially at multiple disease hotspots, during the 2011–14 crop seasons, carrying only resistant accessions to the next step of evaluation. Wheat accessions which were found to be resistant in the field were then assayed for seedling resistance and profiled using molecular markers. In the primary evaluation, 19,460 accessions were screened at Wellington (Tamil Nadu), a hotspot for wheat rusts. We identified 4925 accessions to be resistant and these were further evaluated at Gurdaspur (Punjab), a hotspot for stripe rust and at Cooch Behar (West Bengal), a hotspot for spot blotch. The second round evaluation identified 498 accessions potentially resistant to multiple rusts and 868 accessions potentially resistant to spot blotch. Evaluation of rust resistant accessions for seedling resistance against seven virulent pathotypes of three rusts under artificial epiphytotic conditions identified 137 accessions potentially resistant to multiple rusts. Molecular analysis to identify different combinations of genetic loci imparting resistance to leaf rust, stem rust, stripe rust and spot blotch using linked molecular markers, identified 45 wheat accessions containing known resistance genes against all three rusts as well as a QTL for spot blotch resistance. The resistant germplasm accessions, particularly against stripe rust, identified in this study can be excellent potential candidates to be employed for breeding resistance into the background of high yielding wheat cultivars through conventional or molecular breeding approaches, and are expected to contribute toward food security at national and global levels.

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Identification, analysis and development of salt responsive candidate gene based SSR markers in wheat

Singh

Chaurasia

Kumar

et al. 2018

BMC Plant Biol

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BackgroundSalinity severely limits wheat production in many parts of the world. Development of salt tolerant varieties represents the most practical option for enhancing wheat production from these areas. Application of marker assisted selection may assist in fast tracking development of salt tolerant wheat varieties. However, SSR markers available in the public domain are not specifically targeted to functional regions of wheat genome, therefore large numbers of these need to be analysed for identification of markers associated with traits of interest. With the availability of a fully annotated wheat genome assembly, it is possible to develop SSR markers specifically targeted to genic regions. We performed extensive analysis to identify candidate gene based SSRs and assessed their utility in characterizing molecular diversity in a panel of wheat genotypes.ResultsOur analysis revealed, 161 SSR motifs in 94 salt tolerance candidate genes of wheat. These SSR motifs were nearly equally distributed on the three wheat sub-genomes; 29.8% in A, 35.7% in B and 34.4% in D sub-genome. The maximum number of SSR motifs was present in exons (31.1%) followed by promoters (29.8%), 5’UTRs (21.1%), introns (14.3%) and 3’UTRs (3.7%). Out of the 65 candidate gene based SSR markers selected for validation, 30 were found polymorphic based on initial screening and employed for characterizing genetic diversity in a panel of wheat genotypes including salt tolerant and susceptible lines. These markers generated an average of 2.83 alleles/locus. Phylogenetic analysis revealed four clusters. Salt susceptible genotypes were mainly represented in clusters I and III, whereas high and moderate salt tolerant genotypes were distributed in the remaining two clusters. Population structure analysis revealed two sub-populations, sub-population 1 contained the majority of salt tolerant whereas sub-population 2 contained majority of susceptible genotypes. Moreover, we observed reasonably higher transferability of SSR markers to related wheat species.ConclusionWe have developed salt responsive gene based SSRs in wheat for the first time. These were highly useful in unravelling functional diversity among wheat genotypes with varying responses to salt stress. The identified gene based SSR markers will be valuable genomic resources for genetic/association mapping of salinity tolerance in wheat.Electronic supplementary materialThe online version of this article (10.1186/s12870-018-1476-1) contains supplementary material, which is available to authorized users.

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Root length and root lipid composition contribute to drought tolerance of winter and spring wheat

et al. 2018

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format for submission Aim: Mechanisms of drought tolerance based on root architecture and lipid composition in wheat are poorly understood. We quantified the differences in root morphological traits and phospholipid and glycolipid levels between winter and spring wheat genotypes differing in drought tolerance were grown at variable water supply. Methods: Experiments were conducted using seven winter and four spring wheat (Triticum aestivum) genotypes. In the first experiment, solid agar medium was used to quantify seminal root angles. In the second experiment, the plants were grown in 150-cm columns in a greenhouse under full and deficit moisture supply for 65 days to record root architecture. The root tips (2-cm-long) were used for quantifying polar lipids. Results: Winter wheat genotypes had 1.5 times higher maximum root length than spring wheat ones. Significant differences in the content of root polar lipids, and molecular types and double bond index of galactolipids were observed among spring but not winter wheat genotypes. Drought tolerance of winter wheat genotypes was linked with increased maximum root length. In spring wheat, the attributes such as shallow and well-branched root system and increased unsaturated fatty acid content are linked with drought tolerance. Conclusion: Winter wheat genotypes had greater maximum root length and total root length compared with spring wheat genotypes; introgression of this trait into spring wheat background can increase the grain yield under drought stress.

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Combining ability and character association of agronomic and biochemical traits in pea (Pisum sativum L.)

Kumari

Dikshit

Singh

et al. 2015

Scientia Horticulturae

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Estimation of Heterosis for Green Pod Yield and Attributing Characters in Cowpea (Vigna unguiculata (L.) Walp.)

Kumari¹,

Chauhan²

2018

Int.J.Curr.Microbiol.App.Sci

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Jyoti Kumari

Evaluation of 19,460 Wheat Accessions Conserved in the Indian National Genebank to Identify New Sources of Resistance to Rust and Spot Blotch Diseases

Identification, analysis and development of salt responsive candidate gene based SSR markers in wheat

Root length and root lipid composition contribute to drought tolerance of winter and spring wheat

Combining ability and character association of agronomic and biochemical traits in pea (Pisum sativum L.)

Estimation of Heterosis for Green Pod Yield and Attributing Characters in Cowpea (Vigna unguiculata (L.) Walp.)

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