Genome-Wide Discovery and Deployment of Insertions and Deletions Markers Provided Greater Insights on Species, Genomes, and Sections Relationships in the Genus Arachis

Vishwakarma, Manish K.; Kale, Sandip M.; Sriswathi, Manda; Naresh, T; Shasidhar, Yaduru; Garg, Vanika; Pandey, Manish K.; Varshney, Rajeev K.

doi:10.3389/fpls.2017.02064

Cited by 31 publications

(22 citation statements)

References 52 publications

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“…The IPGI-led diploid genomes of A. duranensis (A genome) and A. ipaensis (B genome) were mined for SSRs leading to identification of 135,529 and 199,957 SSRs, respectively (Zhao et al 2017). Further comparative diploid genome analysis with each other also identified 515,223 InDels, i.e., 269,973 insertions and 245,250 deletions by comparing A. duranensis with A. ipaënsis (Vishwakarma et al 2017b). The genome sequence can also be used as reference genome for The developed genetic markers can be used in various purposes for enhancing breeding efficiency such as molecular breeding product development as well as in ensuring genetic purity in seed chain 1 3 single nucleotide polymorphism (SNP) calling which are the most abundant structural variation across the genome.…”

Section: Resequencing and Genome-wide Genetic Markersmentioning

confidence: 99%

Translational genomics for achieving higher genetic gains in groundnut

Pandey

Kumar

et al. 2020

Theor Appl Genet

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Key message Groundnut has entered now in post-genome era enriched with optimum genomic and genetic resources to facilitate faster trait dissection, gene discovery and accelerated genetic improvement for developing climate-smart varieties. Abstract Cultivated groundnut or peanut (Arachis hypogaea), an allopolyploid oilseed crop with a large and complex genome, is one of the most nutritious food. This crop is grown in more than 100 countries, and the low productivity has remained the biggest challenge in the semiarid tropics. Recently, the groundnut research community has witnessed fast progress and achieved several key milestones in genomics research including genome sequence assemblies of wild diploid progenitors, wild tetraploid and both the subspecies of cultivated tetraploids, resequencing of diverse germplasm lines, genome-wide transcriptome atlas and cost-effective high and low-density genotyping assays. These genomic resources have enabled high-resolution trait mapping by using germplasm diversity panels and multi-parent genetic populations leading to precise gene discovery and diagnostic marker development. Furthermore, development and deployment of diagnostic markers have facilitated screening early generation populations as well as marker-assisted backcrossing breeding leading to development and commercialization of some molecular breeding products in groundnut. Several new genomics applications/technologies such as genomic selection, speed breeding, mid-density genotyping assay and genome editing are in pipeline. The integration of these new technologies hold great promise for developing climate-smart, high yielding and more nutritious groundnut varieties in the post-genome era.

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Section: Resequencing and Genome-wide Genetic Markersmentioning

confidence: 99%

Translational genomics for achieving higher genetic gains in groundnut

Pandey

Kumar

et al. 2020

Theor Appl Genet

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“…Availability of reference genome and high density genotyping assay are the most important milestones for understanding genome architecture, trait mapping, gene discovery, and molecular breeding (Varshney et al, 2013). The major genomic resources that have been developed in recent years include 1) reference genome of cultivated tetraploid (Bertioli et al, 2019;Chen et al, 2019;Zhuang et al, 2019); 2) reference genome of allotetraploid wild groundnut, Arachis monticola (Yin et al, 2018); 3) reference genomes of diploid progenitors of cultivated groundnut i.e., A. duranensis (Bertioli et al, 2016;Chen et al, 2016) and A. ipaensis (Bertioli et al, 2016;Lu et al, 2018); 4) "Axiom_Arachis" array, a high density genotyping assay with >58K highly informative SNPs (Pandey et al, 2017a); 5) gene expression atlas for cultivated tetraploid (Clevenger et al, 2016); 6) molecular/ genetic markers (Pandey et al, 2016;Pandey et al, 2017a;Vishwakarma et al, 2017;Zhao et al, 2017;Lu et al, 2019;Pandey et al, 2019b;Pandey et al, 2019c); and 7) diverse genetic populations such as MAGIC and nested association mapping (NAM) populations to conduct high resolution genetic mapping and breeding (Pandey et al, 2017a;Pandey et al, 2017b;Pandey et al, 2017c); and 8) trait linked diagnostic markers for use in genomics-assisted breeding (GAB) (Pandey et al, 2017c). As a result, the next-generation sequencing based trait discovery (Pandey et al, 2017b) and sequence-based breeding (Varshney et al, 2019) will enhance breeding speed and precision for greater genetic gains.…”

Section: Exploiting the Diploid And Tetraploid Groundnut Genome Sequementioning

confidence: 99%

Advances in Crop Improvement and Delivery Research for Nutritional Quality and Health Benefits of Groundnut (Arachis hypogaea L.)

et al. 2020

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“…There has been tremendous progress in the development of genomic resources for peanut over the last decade, and details of these resources have been reviewed time to time (see Pandey et al 2012Pandey et al , 2014Varshney et al 2013;Ozias-Akins et al 2017;Vishwakarma et al 2017a). Six major resources are very useful for peanut research community including (i) reference genome of diploid progenitor species, i.e., Arachis duranensis (Bertioli et al 2016;Chen et al 2016) and A. ipaensis of cultivated groundnut (Bertioli et al 2016), (ii) high-density genotyping array "Axiom_ Arachis" with >58 K highly informative single nucleotide polymorphisms (SNPs) (Pandey et al 2017a), (iii) gene expression atlas (Clevenger et al 2016), (iv) genome-wide simple sequence repeat (SSR) and insertion/deletion markers (Zhao et al 2017;Vishwakarma et al 2017b), (v) next-generation genetic populations for high-resolution genetic mapping and breeding (see Pandey et al 2016), and (vi) trait-linked diagnostic markers for use in GAB (see Vishwakarma et al 2017a).…”

Section: Genomic Resources: No More Issue For Genomics and Breeding Amentioning

confidence: 99%

Groundnut Entered Post-genome Sequencing Era: Opportunities and Challenges in Translating Genomic Information from Genome to Field

Pandey

Varshney

2018

Biotechnologies of Crop Improvement, Volume 3

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Cultivated groundnut or peanut (Arachis hypogaea) is an allopolyploid crop with a large complex genome and genetic barrier for exchanging genetic diversity from its wild relatives due to ploidy differences. Optimum genetic and genomic resources are key for accelerating the process for trait mapping and gene discovery and deploying diagnostic markers in genomics-assisted breeding. The better utilization of different aspects of peanut biology such as genetics, genomics, transcriptomics, proteomics, epigenomics, metabolomics, and interactomics can be of great help to groundnut genetic improvement program across the globe. The availability of high-quality reference genome is core to all the "omics" approaches, and hence optimum genomic resources are a must for fully exploiting the potential of modern science into conventional breeding. In this context, groundnut is passing through a very critical and transformational phase by making available the required genetic and genomic resources such as reference genomes of progenitors, resequencing of diverse lines, transcriptome resources, germplasm diversity panel, and multi-parent genetic populations for conducting high-resolution trait mapping, identification of associated markers, and development of diagnostic markers for selected traits. Lastly, the available resources have been deployed in translating genomic information from genome to field by developing improved groundnut lines with enhanced resistance to rootknot nematode, rust, and late leaf spot and high oleic acid. In addition, the International Peanut Genome Initiative (IPGI) have made available the high-quality reference genome for cultivated tetraploid groundnut which will facilitate better utilization of genetic resources in groundnut improvement. In parallel, the development of highdensity genotyping platforms, such as Axiom_Arachis array with 58 K SNPs, and

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Genome-Wide Discovery and Deployment of Insertions and Deletions Markers Provided Greater Insights on Species, Genomes, and Sections Relationships in the Genus Arachis

Cited by 31 publications

References 52 publications

Translational genomics for achieving higher genetic gains in groundnut

Translational genomics for achieving higher genetic gains in groundnut

Advances in Crop Improvement and Delivery Research for Nutritional Quality and Health Benefits of Groundnut (Arachis hypogaea L.)

Groundnut Entered Post-genome Sequencing Era: Opportunities and Challenges in Translating Genomic Information from Genome to Field

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