Translational genomics for achieving higher genetic gains in groundnut

Pandey, Manish K.; Pandey, Arun K.; Kumar, Rakesh; Nwosu, Chogozie Victor; Guo, Bao‐Zhu; Wright, Graeme C.; Bhat, Ramesh; Chen, Xiaoping; Bera, SK; Yüan, Ming; Jiang, Huifang; Faye, Issa; Radhakrishnan, T.; Wang, Xingjun; Liang, Xuanquiang; Liao, Boshou; Zhang, Xinyou; Varshney, Rajeev K.; Zhuang, Weijian

doi:10.1007/s00122-020-03592-2

Cited by 67 publications

(54 citation statements)

References 84 publications

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“…Furthermore, groundnut is also a vibrant ingredient in numerous delicious commercial products (Pandey et al, 2012;Pandey and Varshney, 2018). Besides, groundnut being a legume crop is an important candidate for crop rotation resulting soil enrichment and fertility via atmospheric nitrogen fixation and breaking pest and disease cycles (Pandey et al, 2020).…”

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confidence: 99%

Genetic Variability, Traits Association and Path Coefficient Analysis in Advanced Lines of Groundnut (Arachis hypogaea L.)

Jahanzaib¹,

Nawaz²,

Arshad³

et al. 2021

JIS

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G roundnut (Arachis hypogaea L.) is an allotetraploid (2n=4x=40), most probably originated in the region of eastern foothills of Andes, Southern Bolivia, and Northern Argentina (Hampannavar and Khan, 2019). It is widely grown as an oilseed and food crop in more than 144 countries worldwide, where commercial production mostly confined between 40°S and 40°N latitudes. Groundnut is presumed to be domesticated in South America about 6 thousand years ago followed by widely distribution in post-Columbian times. As a rich source of seed oil (~46-58%) and protein (~22-32%), it has great potential to cope with the problem of malnutrition and to ensure food security (Zhuang et al., 2019). Groundnut is also a good source of minerals and vitamins including vitamin E, niacin, phosphorus, falcin, calcium,) is an important grain legume crop. However, there is still great need to develop superior varieties and lift its production. Germplasm characterization plays a vital role in improved cultivars' development. The current study was conducted to estimate genetic variability, traits association, and path coefficient analysis in eleven groundnut advanced breeding lines together with check vis BARD-479, using randomized complete block design with three replications at National Agricultural Research Centre, Islamabad, Pakistan. Through One-Way Analysis of variance significant discrepancies were found among the genotypes for most of the traits. In this study 100 kernels weight was found in significant positive correlation (0.821 **) with twenty pods length, while in significant negative correlation (-0.850 **) with plant width. Similarly, the trait of dry pods yield was in significant positive correlation (1.216**) with plant height, while was significant negatively correlated (-.850**) with number of branches. A strong positive direct effect was observed between twenty pods length (5.548), shelling percentage (4.630), 100-kernels weight (3.738), and leaflet length (2.950) with dry pods yield, indicating the importance of traits linkage in groundnut genotypes improvement. A weak direct effect was found among morphological traits i.e., number of branches (1.419), plant height (.311), and plant width (1.058). A strong indirect effect was witnessed by Leaflet width (-2.225) with dry pods yield. Furthermore, genotypes PG-1221, PG-1259, PG-1254, and PG-1266 were found with promising yield potential of 3637 Kg/ha, 3430 Kg/ha, 3286 Kg/ha, and 3176 Kg/ha, respectively, hence recommended for further evaluation through future breeding program.

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confidence: 99%

Genetic Variability, Traits Association and Path Coefficient Analysis in Advanced Lines of Groundnut (Arachis hypogaea L.)

Jahanzaib¹,

Nawaz²,

Arshad³

et al. 2021

JIS

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“…Marker‐assisted backcrossing (MABC) breeding has been successfully deployed for improving biotic, abiotic, and nutrition related traits in several crops (Kang et al., 2019; Oladosu et al., 2020; Prasanna et al., 2020; Singh, Sharma, Varshney, Sharma, & Singh, 2008; Thudi et al., 2014b) including legumes (Bohra, Saxena, Varshney, & Saxena, 2020; Pandey et al., 2020; Roorkiwal et al., 2020; Varshney, 2016). In the case of chickpea, superior lines with enhanced drought tolerance (Varshney et al., 2013a) and resistance to Fusarium wilt and Ascochyta blight have been reported using the MABC approach (Mannur et al., 2019; Pratap et al., 2017; Varshney et al., 2014b).…”

Section: Introductionmentioning

confidence: 99%

Introgression of “QTL‐hotspot” region enhances drought tolerance and grain yield in three elite chickpea cultivars

et al. 2021

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With an aim of enhancing drought tolerance using a marker-assisted backcrossing (MABC) approach, we introgressed the "QTL-hotspot" region from ICC 4958 accession that harbors quantitative trait loci (QTLs) for several drought-tolerance related traits into three elite Indian chickpea (Cicer arietinum L.) cultivars: Pusa 372, Pusa 362, and DCP 92-3. Of eight simple sequence repeat (SSR) markers in the QTLhotspot region, two to three polymorphic markers were used for foreground selection with respective cross-combinations. A total of 47, 53, and 46 SSRs were used for background selection in case of introgression lines (ILs) developed in genetic backgrounds of Pusa 372, Pusa 362, and DCP 92-3, respectively. In total, 61 ILs (20 BC 3 F 3 in Pusa 372; 20 BC 2 F 3 in Pusa 362, and 21 BC 3 F 3 in DCP 92-3), with >90% recurrent parent genome recovery were developed. Six improved lines in different genetic backgrounds (e.g. BGM 10216 in Pusa 372; BG 3097 and BG 4005 in Pusa 362; IPC(L4-14), IPC(L4-16), and IPC(L19-1) in DCP 92-3) showed better performance than their respective recurrent parents. BGM 10216, with 16% yield gain over Pusa 372, has been released as Pusa Chickpea 10216 by the Central SubCommittees on Crop Standards, Notification and Release of Varieties of Agricultural Crops, Ministry of Agriculture and Farmers Welfare, Government of India, for commercial cultivation in India. In summary, this study reports introgression of the QTL-hotspot

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“…Acute iron deficiency can lead to plant death and even complete crop failure. In order to sustain high productivity and wider adaptation under these challenging growing conditions, the development of new groundnut varieties with improved genetics considering such major constraints are required for better adoption in farmer’s field [ 10 ].…”

Section: Introductionmentioning

confidence: 99%

Improved Genetic Map Identified Major QTLs for Drought Tolerance- and Iron Deficiency Tolerance-Related Traits in Groundnut

Pandey

Gangurde

Sharma

et al. 2020

Genes

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A deep understanding of the genetic control of drought tolerance and iron deficiency tolerance is essential to hasten the process of developing improved varieties with higher tolerance through genomics-assisted breeding. In this context, an improved genetic map with 1205 loci was developed spanning 2598.3 cM with an average 2.2 cM distance between loci in the recombinant inbred line (TAG 24 × ICGV 86031) population using high-density 58K single nucleotide polymorphism (SNP) “Axiom_Arachis” array. Quantitative trait locus (QTL) analysis was performed using extensive phenotyping data generated for 20 drought tolerance- and two iron deficiency tolerance-related traits from eight seasons (2004–2015) at two locations in India, one in Niger, and one in Senegal. The genome-wide QTL discovery analysis identified 19 major main-effect QTLs with 10.0–33.9% phenotypic variation explained (PVE) for drought tolerance- and iron deficiency tolerance- related traits. Major main-effect QTLs were detected for haulm weight (20.1% PVE), SCMR (soil plant analytical development (SPAD) chlorophyll meter reading, 22.4% PVE), and visual chlorosis rate (33.9% PVE). Several important candidate genes encoding glycosyl hydrolases; malate dehydrogenases; microtubule-associated proteins; and transcription factors such as MADS-box, basic helix-loop-helix (bHLH), NAM, ATAF, and CUC (NAC), and myeloblastosis (MYB) were identified underlying these QTL regions. The putative function of these genes indicated their possible involvement in plant growth, development of seed and pod, and photosynthesis under drought or iron deficiency conditions in groundnut. These genomic regions and candidate genes, after validation, may be useful to develop molecular markers for deploying genomics-assisted breeding for enhancing groundnut yield under drought stress and iron-deficient soil conditions.

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Translational genomics for achieving higher genetic gains in groundnut

Cited by 67 publications

References 84 publications

Genetic Variability, Traits Association and Path Coefficient Analysis in Advanced Lines of Groundnut (Arachis hypogaea L.)

Genetic Variability, Traits Association and Path Coefficient Analysis in Advanced Lines of Groundnut (Arachis hypogaea L.)

Introgression of “QTL‐hotspot” region enhances drought tolerance and grain yield in three elite chickpea cultivars

Improved Genetic Map Identified Major QTLs for Drought Tolerance- and Iron Deficiency Tolerance-Related Traits in Groundnut

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