<scp>QTL</scp>‐seq approach identified genomic regions and diagnostic markers for rust and late leaf spot resistance in groundnut (<i><scp>A</scp>rachis hypogaea </i><scp>L</scp>.)

Pandey, Manish K.; Khan, Aamir W.; Singh, Vikas K.; Vishwakarma, Manish K.; Shasidhar, Yaduru; Kumar, Vinay; Garg, Vanika; Bhat, Ramesh; Chitikineni, Annapurna; Janila, Pasupuleti; Guo, Bao‐Zhu; Varshney, Rajeev K.

doi:10.1111/pbi.12686

Cited by 187 publications

(203 citation statements)

References 43 publications

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“…The two major QTLs for ELS on LG B03 were flanked by homeologous markers from chromosome A03, suggesting that these regions of chromosome A03 may constitute a hot spot for genes responsible for ELS resistance. In a recent study using QTL‐seq approach in a TAG24 × GPBD4 RIL population, a 2.98 Mb (131.67–134.65 Mb) genomic region on chromosome A03, which overlaps with the region indicated in the present study to contain these two major ELS‐resistant QTLs (132.10–132.20 Mb and 133.65–133.73 Mb, respectively), was also found to contribute to LLS resistance (Pandey et al ., ). This supports the notion that this region on chromosome A03 has genes playing role in defence against leaf spots.…”

Section: Discussionmentioning

confidence: 97%

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High‐density genetic map using whole‐genome resequencing for fine mapping and candidate gene discovery for disease resistance in peanut

Agarwal

Clevenger

Pandey

et al. 2018

Plant Biotechnology Journal

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SummaryWhole‐genome resequencing (WGRS) of mapping populations has facilitated development of high‐density genetic maps essential for fine mapping and candidate gene discovery for traits of interest in crop species. Leaf spots, including early leaf spot (ELS) and late leaf spot (LLS), and Tomato spotted wilt virus (TSWV) are devastating diseases in peanut causing significant yield loss. We generated WGRS data on a recombinant inbred line population, developed a SNP‐based high‐density genetic map, and conducted fine mapping, candidate gene discovery and marker validation for ELS, LLS and TSWV. The first sequence‐based high‐density map was constructed with 8869 SNPs assigned to 20 linkage groups, representing 20 chromosomes, for the ‘T’ population (Tifrunner × GT‐C20) with a map length of 3120 cM and an average distance of 1.45 cM. The quantitative trait locus (QTL) analysis using high‐density genetic map and multiple season phenotyping data identified 35 main‐effect QTLs with phenotypic variation explained (PVE) from 6.32% to 47.63%. Among major‐effect QTLs mapped, there were two QTLs for ELS on B05 with 47.42% PVE and B03 with 47.38% PVE, two QTLs for LLS on A05 with 47.63% and B03 with 34.03% PVE and one QTL for TSWV on B09 with 40.71% PVE. The epistasis and environment interaction analyses identified significant environmental effects on these traits. The identified QTL regions had disease resistance genes including R‐genes and transcription factors. KASP markers were developed for major QTLs and validated in the population and are ready for further deployment in genomics‐assisted breeding in peanut.

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Section: Discussionmentioning

confidence: 97%

“…Disease resistance is a highly heritable trait of great value to crop production systems. Efforts have been made to identify the QTLs/candidate genes for important diseases such as ELS, LLS and TSWV in peanut (Khera et al ., ; Pandey et al ., ,). In the present study, 20 QTLs were identified on A‐subgenome LGs and 15 on B‐subgenome LGs.…”

Section: Discussionmentioning

confidence: 99%

High‐density genetic map using whole‐genome resequencing for fine mapping and candidate gene discovery for disease resistance in peanut

Agarwal

Clevenger

Pandey

et al. 2018

Plant Biotechnology Journal

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“…In parallel, we need to have diagnostic markers with higher prediction accuracy and candidate genes with causal effect for a given trait. For trait discovery, instead of using a traditional mapping approach, it is possible now to use sequencing-based trait mapping approaches such as QTL-Seq, Bulk-Seq and Indel-Seq Pandey et al, 2017b). Similarly, recent advances in functional genomics such as gene expression atlases (Pazhamala et al, 2017) and use of near-isogenic lines for transcriptomics approaches can identify the candidate genes for the target traits.…”

Section: Integrated and Coordinated Approachmentioning

confidence: 99%

Accelerating genetic gains in legumes for the development of prosperous smallholder agriculture: integrating genomics, phenotyping, systems modelling and agronomy

Varshney

Thudi

Pandey

et al. 2018

Journal of Experimental Botany

101

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Grain legumes form an important component of the human diet, provide feed for livestock, and replenish soil fertility through biological nitrogen fixation. Globally, the demand for food legumes is increasing as they complement cereals in protein requirements and possess a high percentage of digestible protein. Climate change has enhanced the frequency and intensity of drought stress, posing serious production constraints, especially in rainfed regions where most legumes are produced. Genetic improvement of legumes, like other crops, is mostly based on pedigree and performance-based selection over the past half century. To achieve faster genetic gains in legumes in rainfed conditions, this review proposes the integration of modern genomics approaches, high throughput phenomics, and simulation modelling in support of crop improvement that leads to improved varieties that perform with appropriate agronomy. Selection intensity, generation interval, and improved operational efficiencies in breeding are expected to further enhance the genetic gain in experimental plots. Improved seed access to farmers, combined with appropriate agronomic packages in farmers' fields, will deliver higher genetic gains. Enhanced genetic gains, including not only productivity but also nutritional and market traits, will increase the profitability of farming and the availability of affordable nutritious food especially in developing countries.

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“…Through ddRADseq, high-throughput genotyping method using NGS technology, total 14,663 SNPs were developed and SNP-based genetic linkage map with 1,765 SNP markers was constructed. Pandey et al (2017) successfully applied QTL-seq approach based on whole-genome re-sequencing in peanut and allele-specific diagnostic markers were identified for three SNPs for rust resistance and one SNP for late leaf spot resistance.…”

Section: Introductionmentioning

confidence: 99%

“…In the case of peanut, reference sequences of two donor diploid species composing peanut have released in 2016 (1,211 Mb for A. duranensis and 1,512 Mb for A. ipaensis). Based on the diploid reference genome sequences, research focusing on identifying genes and SNP associated with important traits are underway (Bertioli et al 2016;Zhao et al 2016;Pandey et al 2017).…”

Section: Introductionmentioning

confidence: 99%

Development of SNP-Based Molecular Markers by Re-Sequencing Strategy in Peanut

KiSeung¹,

Lee

Bae

et al. 2017

Plant Breed. Biotech.

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This is an Open-Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/4.0) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited. ABSTRACT The objective of this study was to develop high-throughput SNP or SNP-based markers by re-sequencing of two peanut cultivars, 'K-Ol' and 'Pungan'. The whole genome re-sequencing for the two cultivars was performed to produce sequences of 35.3 × 10 9 bp with 350 × 10 6 reads and 32.0 × 10 9 bp with 318 × 10 6 reads, respectively. As compared with the peanut reference genome, the distribution of homozygous and heterozygous SNPs on each chromosome showed very similar patterns between 'K-Ol' and 'Pungan', and most of them were in intergenic-region regardless of the peanut cultivars and reference genome type. The SNPs identified between the two peanut cultivars were evenly distributed across chromosomes of peanut diploid A and B reference genomes. It indicated that these SNPs could be available to construct a genetic map using the segregating population derived from a cross between 'K-Ol' and 'Pungan'. Total 61 CAPS marker were developed and tested for their availability. Of the CAPS markers, 60 CAPS markers produced normal PCR products and 18 out of them presented polymorphism among 6 peanut varieties. Results of the present study could provide useful genetic resources to facilitate marker-assisted selection for breeding programs as well as germplasm screening for peanut.

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QTL‐seq approach identified genomic regions and diagnostic markers for rust and late leaf spot resistance in groundnut (Arachis hypogaea L.)

Cited by 187 publications

References 43 publications

High‐density genetic map using whole‐genome resequencing for fine mapping and candidate gene discovery for disease resistance in peanut

High‐density genetic map using whole‐genome resequencing for fine mapping and candidate gene discovery for disease resistance in peanut

Accelerating genetic gains in legumes for the development of prosperous smallholder agriculture: integrating genomics, phenotyping, systems modelling and agronomy

Development of SNP-Based Molecular Markers by Re-Sequencing Strategy in Peanut

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